Method and apparatus for detecting photoacoustic signal

ABSTRACT

A method and an apparatus for detecting a photoacoustic signal are provided which irradiate an excitation light beam, modulated by a desired frequency, simultaneously to a plurality of points being measured on a surface of a sample, irradiate the excitation light and a probe light simultaneously to the plurality of the points being measured, detect an interference light of a reflected light beam of the probe light and a specified reference light with a detector made up of a plurality of photoelectric converting elements corresponding to the respective points being measured, the detector being in conjugate relation with the surface of the sample, detect a thermal distortion of the frequency component equal to the intensity-modulated frequency at the plurality of the points being measured from the interference light intensity signal detected by the detector, and detect information relative to the surface and the subsurface of the measuring points on the sample from the thermal distortion of the frequency component.

CROSS-REFERENCE TO RELATED APPLICATION

This is a continuation-in-part of U.S. application Ser. No. 07/886,014, filed on May 20, 1992, now U.S. Pat. No. 5,377,006 the disclosure of which is hereby incorporated by reference.

BACKGROUND OF THE INVENTION

The present invention relates to a method and an apparatus for detecting a photoacoustic signal to detect information relative to the surface and the subsurface of a sample using photoacoustic or photothermal effect, and more particularly to a method and an apparatus for detecting a photoacoustic signal, devised to effectively correct abnormality of phase shifts by phase jumps at specified points of the sample when a photoacoustic signal is detected at those points of the sample.

The photoacoustic effect was discovered by Tyndall, Bell, Roentgen, et al. in 1881. As shown in FIG. 2, when intensity-modulated light (intermittent light beam) 19 is irradiated to a sample 7 by focusing the light as an excitation light with a lens 5, heat is generated in a light absorption region V_(OP) 21, and periodically diffused through a thermal diffusion region V_(th) 23 defined by a thermal diffusion length μ_(S) 22 so that the resulting thermal distortion wave gives rise to a thermoelastic wave (ultrasonic wave). By detecting this ultrasonic wave, i.e. a photoacoustic wave by a microphone (acousto-electric converter) or by a piezo-electric or a light interferometer to thereby obtain a signal component synchronized with the modulated frequency of the excitation light, information relative to the surface and subsurface of the sample can be obtained. Incidentally, the thermal diffusion length μ_(S) 22 can be obtained by the following expression (1) from the thermal conductivity k, density ρ, and specific heat c of the sample 7 when the modulated frequency of the excitation light is denoted by f_(L). ##EQU1##

A technique for detecting the above photoacoustic signal is disclosed, for example, in "HIHAKAI KENSA", Vol. 36, No. 10 issue, pp. 730-736 October 1987 (Showa 62) or IEEE 1986 ULTRASONIC SYMPOSIUM pp. 515-526 (1986).

Referring to FIG. 1, one example of such a technique will be explained. A parallel light beam emitted from a laser 1 is intensity-modulated by an acousto-optical modulator (A0 modulator) 2. The thus obtained intermittent light is expanded to a parallel beam of a desired diameter by a beam expander 3, which is reflected by a half mirror 4, and then focused by a lens 5 on the surface of the sample 7 placed on an X-Y stage 6. The thermal distortion wave emanating from the focusing position 21 on the sample 7 generates a thermoelastic wave, thus causing minute displacements at the surface of the sample. The minute displacements will be detected by a Michelson interferometer explained below. After the parallel light beam from the laser 8 is expanded to a desired beam diameter by the beam expander 9, the beam is separated into two beams traveling along two optical paths by a beam splitter or a half mirror 10. One is focused at the focusing position 21 on the sample by the lens 5, while the other is irradiated to a reference mirror 11. Then, the light reflected from the sample 7 and the light reflected from the reference mirror 11 interfere with each other at the half mirror 10. The interference light is focused by a lens 12 on a photoelectric converting element 13 such as a photodiode by a lens 12 to provide a photoelectric-converted interference intensity signal. After amplified by a preamplifier 14, the interference intensity signal is sent to a lock-in amplifier 16. Using a modulation frequency signal from an oscillator 15 used to drive the acousto-optical modulator 2 as a reference signal, the lock-in amplifier 16 extracts only the modulated frequency component contained in the interference intensity signal. This frequency component has information relative to the surface or the inside of the sample 7. According to the expression (1), by varying the modulated frequency, the thermal diffusion length μ_(S) 21 can be changed and information as to the condition through the depth of the sample can be obtained. If there is a defect such as a crack in the thermal diffusion region V_(th) 23, the amplitude of the modulated frequency component in the interference light intensity signal and the phase thereof relative to the modulation frequency signal change, by which the presence of the defect can be known. An X-Y stage shifting signal and an output signal from the lock-in amplifier 16 are processed by a computer 17. Accordingly, the photoacoustic signal corresponding to the respective points on the sample can be gathered and displayed as a two-dimensional image on a display 18 such as a monitor television.

Though the above-mentioned prior-art technique is extremely effective means for detecting a photoacoustic signal in non-contact and non-destructive inspection of samples, but has the following problems.

In the conventional photoacoustic detection optical system as shown in FIG. 1, when a two-dimensional internal information of a sample is to be obtained, it is necessary to perform a two-dimensional scanning of the surface of a sample by a relative motion of two beams, that is, an excitation light for generating a photoacoustic effect and a probe light for detecting minute displacements of the sample surface caused by the photoacoustic effect. This two-dimensional scanning is the so-called point scanning by which information is obtained point by point, and therefore, if one tries to scan the whole surface of the sample, a very large amount of detection time is required. This necessity for a large amount of detection time is the greatest reason why the photoacoustic detection technique has not been applied to internal defect inspection of samples in the production line. In some samples, the reflectance of the surface varies with different positions of the sample. In such a case, with the prior-art technique, the intensity of the reflected light of the probe light unavoidably contains information relative to the surface reflectance in addition to information about the internal condition, so that it is difficult to accurately detect only information about the inside of the sample. Furthermore, in some samples, the surface is not flat and has local undulations. In this case, in the prior-art technique, the phase of the reflected beam of the probe light varies according to the undulations of the sample surface, so that the reflected light intensity includes information with regard to the surface undulations in addition to internal information and, as a result, it is difficult to accurately detect only internal information about the internal condition.

Moreover, in the conventional photoacoustic signal detection method, there is no way to cope with the phenomenon called "phase jump". Suppose a case in which a photoacoustic signal is detected from a sample 200 having a crack 109 in the surface, as shown in FIG. 3A, for example. FIG. 3B shows a longitudinal sectional view taken along the line A--A' in FIG. 3A, while FIG. 4A shows a phase shift image (hereafter referred to as the phase image) of two-dimensional photoacoustic images of the sample 200. In the phase image, the thin white region corresponds to the crack 109, and in this region, there are several dark areas where the phase shift occurs sharply. FIG. 4B shows a phase shift signal 111 in a section taken along the line B--B' in FIG. 4A. As is apparent from this figure, there is a sharp phase jump in the dark areas, and in those areas, the phase signal 111 shows a sharp drop and rebound.

Generally, out of various photoacoustic signals, the phase signal has a characteristic that when the phase signal exceeds +π, the phase changes -2π relative to the phase value, and similarly, when the phase signal exceeds -π, the phase changes 2π relative to the phase value. In this patent application, those changes are defined as the so-called "phase jump". This phase jump phenomenon occurs in the extraction of phase shift from the photoacoustic signal. More specifically, in the lock-in amplifier 16 in FIG. 1 the photoacoustic signal (interference intensity signal) is separated into a cosine component X and a sine component Y as shown by the expressions (1) and (2). The amplitude A and the phase θ of the photoacoustic signal can be obtained by the expressions (3) and (4). ##EQU2##

As shown in the expression (4), the phase shift θ can be obtained as an arctangent of a rate of the sine component Y to the cosine component X. As is well known, the principal value of the arctangent in this case exists in the range of +π to -π. Therefore, for example, when the phase shift θ has a value (π+β), which exceeds +π, the value output from the lock-in amplifier is -π+β, that is, π+β added with -2π. Likewise, when the phase shift has a value (-π-β) less than -π, the output value is π-β, that is, -π-β added with +2π. In this way, a phase jump occurs. Therefore, when a phase jump has occurred at a sampling point, the real situation is that the phase shift at this sampling point does not contain a correct phase shift information, and for this reason, information relative to the surface and the inside of the sample cannot be obtained securely.

SUMMARY OF THE INVENTION

Therefore, an object of the present invention is to provide a method and an apparatus, in a simple arrangement, for detecting a photoacoustic signal, which are less susceptible to effects of the reflectance distribution and the undulations distribution and which enable high-speed detection of two-dimensional internal information of a sample.

In order to achieve the above object, in accordance with the present invention, an intensity-modulated light is irradiated to a plurality of points being measured on a surface of a sample to generate a photoacoustic effect or a photothermal effect either on the surface or the inside of the plurality of points being measured, and at the same time, a light beam is irradiated to a plurality of points being measured, the reflected light and a reference light are made to interfere with each other, the resulting interference light is detected by a detector in a conjugate relation with the surface of the sample, said detector comprising a plurality of photoelectric converting elements corresponding to the respective points being measured, and from the detected interference light intensity signal, thermal distortion of the frequency component equal to the above-mentioned intensity-modulated frequency at the plurality of points being measured is detected. This method enables almost simultaneous extraction of information relative to the surface and the inside of a plurality of points being measured of a sample, and also enables detection of a photoacoustic signal at far higher speed than in the prior-art detection method.

Further, in order to achieve the above object, according to the present invention, the intensity-modulated light irradiated to the sample is formed as a continuous and straight beam on the sample, and a plurality of points being measured on the sample can be excited simultaneously, so that a photoacoustic signal can be detected at far higher speed than in the prior-art technique.

Further, in order to achieve the above object, according to the present invention, the intensity-modulated light, irradiated to the sample, is formed in a straight row of spot beams arranged on the sample, a plurality of points being measured on the sample can be excited simultaneously, so that a photoacoustic signal can be detected at far higher speed than in the prior-art technique.

In order to achieve the above object, according to the present invention, the above-mentioned spot beams in a row are arranged at such intervals that thermal diffusion regions by the spot beams do not overlap one another, thus improving the detection resolution of a photoacoustic image.

In order to achieve the above object, according to the present invention, by using a detector comprising a plurality of storage type photoelectric converting elements for detecting an interference light, a photoacoustic signal can be detected at far higher speed than in the prior-art method.

In order to achieve the above object, according to the present invention, by using a detector comprising a plurality of non-storage type photoelectric converting elements for detecting an interference light, a photoacoustic signal can be detected at far higher speed than in the prior-art method.

In order to achieve the above object, according to the present invention, by using a detector which outputs an interference light intensity signal from a plurality of photoelectric converting elements as a one-dimensional signal in time sequence, a photoacoustic signal can be detected at far higher speed than in the prior-art method.

In order to achieve the above object, according to the present invention, by using a detector which does parallel and simultaneous output of an interference light intensity signal from a plurality of photoelectric converting elements, a photoacoustic signal can be detected at far higher speed than in the prior-art method.

In order to achieve the above object, according to the present invention, by using a detector comprising a plurality of storage type photoelectric converting elements to detect an interference light, the interference light intensity signal, which is stored in a desired storage time and output from each of the storage type photoelectric converting elements of the detector, is detected 2n n:arbitrary integer, >0 times by shifting the phase of the signal by π/n for each photoelectric converting element, and according to 2n pieces of signal data, the thermal distortion of the frequency component equal to the above-mentioned intensity-modulated frequency is calculated, and thereby use of a digital frequency filtering process is made possible instead of an analog frequency filtering process, so that detection of a photoacoustic signal can be performed with high sensitivity and high accuracy without being much affected by a high harmonic component. Furthermore, it is possible with only one detector to simultaneously detect a total of four items of information relative to the surface and the inside of the sample, namely, the reflectance distribution of the sample surface, the undulations distribution of the sample surface, the amplitude distribution of the photoacoustic signal, and the phase distribution of the photoacoustic signal, and thereby a high-speed complex characterization of a sample is made possible. Moreover, according to the present invention, it is possible to detect a photoacoustic signal in which corrections have been made to the reflectance distribution of the sample surface, the undulations distribution of the sample surface, and the optical path fluctuation, so that information relative to the surface and the inside of the sample can be detected with high sensitivity and stability.

In order to achieve the above object, according to the present invention, as a method for shifting the phase of the interference light intensity signal output from the detector, comprising the storage type photoelectric converting elements, by π/n for each photoelectric converting element, a method is used in which a combination of desired values is set for the difference in light frequency between the reflected light from the above-mentioned sample surface and the reference light, the above-mentioned intensity-modulated frequency, and the storage time of the above-mentioned storage type photoelectric converting elements, and therefore, by using only one detector, it is possible to simultaneously detect a total of four items of information as to the surface and the inside of the sample, including the sample surface reflectance distribution, the sample surface undulations distribution, the photoacoustic signal amplitude distribution, and the phase distribution of the photoacoustic signal, and thereby a high-speed complex characterization of a sample is made possible. Also, it is possible to implement photoacoustic signal detection in which corrections have been made to the reflectance distribution of the sample surface, the undulations distribution of the sample surface, and the optical path fluctuation, so that information relative to the surface and the inside of a sample can be detected with high sensitivity and stability.

In order to achieve the above object, according to the present invention, from the interference light intensity signal output in parallel form simultaneously from the detector, the thermal distortion of the frequency component equal to the above-mentioned intensity-modulated frequency is detected with a plurality of photoelectric converting elements in parallel simultaneously.

In order to achieve the above object, according to the present invention, detection of the information of an interface inside the sample is possible by setting the intensity-modulated frequency so that the thermal diffusion length owing to the photoacoustic effect or the photothermal effect is equal to or longer than the depth of the interface in the inside being measured of the above-mentioned sample.

In a photoacoustic signal detection apparatus, by irradiating an intensity-modulated light to a plurality of points being measured on the surface of a sample, a photoacoustic effect or a photothermal effect can be generated at a plurality of points being measured, and at the same time, by irradiating the light to the plurality of points being measured and causing a reflected light from the points being measured and a reference light to interfere with each other, the resulting interference light is detected by a detector, which is in a conjugate relation with the sample surface, the detector comprising a plurality of photoelectric converting elements corresponding to the points being measured, and from the interference light intensity signal detected, the thermal distortion of a frequency component equal to the above-mentioned intensity-modulated frequency at the plurality of points being measured, and thereby information relative to the surface and the inside at the plurality of points being measured of the sample can be extracted substantially simultaneously as a photoacoustic signal, so that detection of a photoacoustic signal can be performed at far higher speed than in the prior-art method.

Further, since the intensity-modulated light is irradiated to the sample in a continuous, straight beam on the sample, the plurality of points being measured on the sample can be excited simultaneously, and detection of a photoacoustic signal can be performed at far higher speed than in the prior-art method.

Further, since the intensity-modulated light is irradiated to the sample in a row of spot beams arranged in a straight line on the sample, the plurality of points being measured on the sample can be excited simultaneously, and detection of a photoacoustic signal can be performed at far higher speed than in the prior-art method.

Further, since the spot beams in a row are arranged at such intervals that the thermal diffusion regions do not overlap each other, the photoacoustic signal can be detected independently from the respective points being measured, thereby improving the detection resolution of a photoacoustic image.

Further, a detector comprising a plurality of storage type photoelectric converting elements is used to detect an interference light, and therefore, the photoacoustic signal at the plurality of points being measured can be extracted substantially simultaneously, which enables detection of a photoacoustic signal at far higher speed than in the prior-art method.

Further, a detector comprising a plurality of non-storage type photoelectric converting elements are used to detect an interference light, and therefore, the photoacoustic signal at the plurality of points being measured is extracted substantially simultaneously, which enables detection of a photoacoustic signal at far higher speed than in the prior-art method.

Further, a detector is used which outputs an interference light intensity signal from a plurality of photoelectric converting elements as a one-dimensional signal in time sequence, and therefore, the photoacoustic signal at the plurality of points being measured can be extracted substantially simultaneously, which enables detection of a photoacoustic signal be performed at far higher speed than in the prior-art method.

Further, a detector is used which outputs an interference light intensity signal from a plurality of photoelectric converting elements in parallel simultaneously, and therefore, the photoacoustic signal at the plurality of points being measured can be extracted substantially simultaneously, which enables detection of a photoacoustic signal at far higher speed than in the prior-art method.

Further, since a detector comprising a plurality of storage type photoelectric converting elements is used to detect an interference light, the interference light intensity signal, which is stored in a desired storage time and output from each of the storage type photoelectric converting elements of the detector, is detected 2n times by shifting the phase of the signal by π/n for each photoelectric converting element, and according to 2n pieces of signal data, the thermal distortion of the frequency component equal to the above-mentioned intensity-modulated frequency is calculated, and thereby use of a digital frequency filtering process is made possible instead of an analog frequency filtering process, so that detection of a photoacoustic signal can be performed with high sensitivity and high accuracy without being much affected by a high harmonic component. Furthermore, it is possible with only one detector to simultaneously detect a total of four items of information relative to the surface and the inside of the sample, namely, the reflectance distribution of the sample surface, the undulations distribution of the sample surface, the amplitude distribution of the photoacoustic signal, and the phase distribution of the photoacoustic signal, and thereby a high-speed complex assessment of a sample is made possible. Moreover, it is possible to detect a photoacoustic signal in which corrections have been made on the reflectance distribution of the sample surface, the undulations distribution of the sample surface, and the optical path fluctuation. Also, information relative to the surface and the inside of the sample can be detected with high sensitivity and stability.

As a method for shifting the phase of the interference light intensity signal output from the detector comprising the storage type photoelectric converting elements by π/n for each photoelectric converting element, a method is used in which a combination of desired values is set for the difference in light frequency between the reflected light from the above-mentioned sample surface and the reference light, the above-mentioned intensity-modulated frequency, and the storage time of the above-mentioned storage type photoelectric converting elements, and therefore, by using only one detector, it is possible to simultaneously detect a total of four items of information relative to the surface and the inside of the sample, which includes the sample surface reflectance distribution, the sample surface undulations distribution, the photoacoustic signal amplitude distribution, and the phase distribution of the photoacoustic signal, and thereby a high-speed complex characterization of a sample is made possible. Also, it is possible to implement photoacoustic signal detection in which corrections have been made on the reflectance distribution of the sample surface, the undulations distribution of the sample surface, and the optical path fluctuation, so that information relative to the surface and the inside of a sample can be detected with high sensitivity and stability.

Further, from the interference light intensity signal output in parallel form simultaneously from the detector, the thermal distortion of the frequency component equal to the above-mentioned intensity-modulated frequency is detected with a plurality of photoelectric converting elements in parallel simultaneously.

Further, the information of an interface inside the sample can be detected by setting the intensity-modulated frequency so that the thermal diffusion length owing to the photoacoustic effect or the photothermal effect is equal to or longer than the depth of the interface in the inside being measured of the above-mentioned sample.

Further, another object of the present invention is to provide a method and an apparatus for detecting a photoacoustic signal, which enables information relative to the surface and the inside of a sample to be detected more stably and with higher accuracy by effectively correcting a phase jump in a phase shift when the phase shift is extracted from the photoacoustic signal.

The above object can be achieved by intensity-modulating a light beam from a light source by a desired frequency, scanning, focusing and irradiating the intensity-modulated light beam on a sample in two dimensions, generating a photoacoustic effect or a photothermal effect on the surface or the inside of the sample to cause a thermal distortion at the sample surface, detecting the thermal distortion at each sampling point, detecting the amplitude of the frequency component synchronized with the above-mentioned intensity-modulated frequency and a phase shift thereof relative to the above-mentioned intensity-modulated signal from the detected signal, detecting the presence or absence of a phase jump in the detected phase shift, correcting the abnormality of the phase shift signal caused by the phase jump when a phase jump is detected in the phase shift, and detecting information relative to the surface and the inside of the sample according to the amplitude and the corrected phase shift.

More specifically, the above object can be achieved by detecting whether a phase jump has occurred in the phase shift detected in each sampling point according to a change in the phase shift, and effectively correcting the abnormality of the phase shift caused by the phase jump at the sampling point where the phase jump has occurred by adding or subtracting 2π to or from the phase shift value at the sampling point according to the change of the phase shift.

Meanwhile, the photoacoustic signal detection apparatus comprises scanning, focusing and irradiating means for intensity-modulating the light from a light source by a desired frequency, scanning, focusing and irradiating the intensity-modulated light on the sample in two dimensions, and causing a thermal distortion on the sample surface by generating a photoacoustic effect or a photothermal effect at the surface or the inside of the sample; thermal distortion detecting means for detecting the thermal distortion at the sampling point caused by the scanning, focusing and irradiating means; amplitude and phase shift detecting means for detecting the amplitude of the frequency component synchronized with the intensity-modulated frequency and a phase shift thereof relative to the intensity-modulated signal from the thermal distortion signal detected by the detecting means; phase jump detecting means for detecting whether a phase jump has occurred in the phase shift detected by the phase detecting means; and correcting means for correcting the abnormality caused by the phase jump when the phase jump is detected in the phase shift by the phase jump detecting means, wherein information relative to the surface and the inside of the sample is detected according to the amplitude detected by the amplitude and detecting means and the phase shift corrected by the correcting means.

More specifically, the above object can be achieved by arranging for the phase jump detecting and correcting means of the photoacoustic signal detection apparatus to effectively correct the abnormality in the phase shift caused by the phase jump at the sampling point by detecting whether a phase jump has occurred in the phase shift detected at each sampling point according to a change of the phase shift, and adding or subtracting 2π to or from the phase shift value at the sampling point where the phase jump has occurred.

In other words, if the phase shift at some sampling point is recognized as a sharp drop or rise compared with the phase shift at a nearby sampling point under a certain condition, a decision is made that a phase jump occurred in the phase shift at that sampling point, the phase shift at the sampling point is corrected by adding 2π or -2π to the phase value at the sampling point. By applying this correction process to the phase shifts at the sampling points which include a phase jump, from the phase shifts at those sampling points, information as to the surface and the subsurface of the sample can be obtained with improved stability and higher accuracy.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 is a diagram showing a structural example of the conventional photoacoustic detection optical system;

FIG. 2 is a diagram showing the principle of a photoacoustic effect;

FIG. 3A is a plan view of a crack in the surface of a sample;

FIG. 3B is a cross-sectional view taken along the line A--A' in FIG. 3A;

FIG. 4A is a two-dimensional photoacoustic image (phase image) of a sample having a surface crack;

FIG. 4B is a phase signal diagram taken along the line B--B' in FIG. 4A;

FIG. 5A is a structural diagram of the photoacoustic detection unit;

FIG. 5B is a diagram of a structural example of the processing unit in FIG. 5A;

FIGS. 6A, 6B, and 6C are diagrams showing modulating signals input to the acousto-optical modulator element;

FIGS. 7A and 7B are structural diagrams of the excitation optical system and the heterodyne interferometric optical system in a first embodiment of the present invention;

FIG. 8 is a perspective view showing a planar structure of a sample, an excitation beam and a probe beam in the first embodiment;

FIGS. 9A and 9B are diagrams showing the cross-sectional structures of the sample and the generated states of a photoacoustic effect by the excitation beam in a stripe form in the first embodiment;

FIGS. 10A and 10B are diagrams showing the polarization direction of the laser beam incident on the heterodyne interference optical system and the orthogonal-polarized beams of two frequencies;

FIGS. 11A and 11B are diagrams showing the incident state on the sample surface of a probe beam in a stripe form in the first embodiment;

FIG. 12 is a diagram showing the polarization directions of the reflected light from the sample, a reference light and a polarizing plate;

FIGS. 13A and 13B are structural diagrams of the detection unit of the heterodyne interferometric optical system in the first embodiment;

FIG. 14 is a diagram showing data structure in a two-dimensional memory;

FIGS. 15A, 15B, and 15C are diagrams showing examples of detection of a photoacoustic signal in the first embodiment;

FIGS. 16A, 16B, and 16C are diagrams of examples of a photoacoustic signal showing the effects of phase correction in the first embodiment;

FIG. 17 is a diagram of the photoacoustic detection optical system in a second embodiment of the present invention;

FIGS. 18A and 18B are diagrams showing structural examples of the excitation optical system in the second embodiment;

FIG. 19 is a perspective view a planar structure of a sample, an excitation beam, a probe beam, and a reference beam in the second embodiment;

FIGS. 20A and 20B are diagrams showing cross-sectional structures of the sample and generated states of a photoacoustic effect by an excitation beam in a stripe form in the second embodiment;

FIGS. 21A and 21B are diagrams showing incident states on the sample surface of a probe beam and a reference beam both in a stripe form in the second embodiment;

FIG. 22 is a structural diagram of the heterodyne interferometric optical system in the second embodiment as seen from the X-axis direction;

FIG. 23 is a structural diagram as seen from the Y-axis direction in FIG. 22;

FIG. 24 is a structural diagram of the detection unit of the heterodyne interferometric optical system in the second embodiment as seen from the X-axis direction;

FIG. 25 is a structural diagram of the detection unit of the heterodyne interferometric optical system shown in FIG. 14 as seen from the Y-axis direction;

FIG. 26 is a diagram of a structural example of the photoacoustic detection apparatus in a third embodiment of the present invention;

FIG. 27 is a diagram of a structural example of the signal processing system in the third embodiment;

FIG. 28 is a diagram of a structural example of the photoacoustic detection apparatus in a fourth embodiment;

FIG. 29 is a diagram of a structural example of a multiple spot beam parallel-irradiation optical system in the fourth embodiment;

FIG. 30 is a diagram showing a shape of a mask of a multiple sport beam parallel-irradiation optical system in the fourth embodiment;

FIG. 31 is a diagram showing simultaneous irradiation of multiple spot beams to the sample in the fourth embodiment;

FIG. 32 is a diagram showing heat diffusion regions produced by the respective spot beams in the fourth embodiment;

FIG. 33 is a flowchart showing an example of a phase jump presence detecting and phase jump correcting process in the present invention;

FIG. 34 is a diagram showing a structure in one example of the photoacoustic signal detection unit according to FIG. 33;

FIG. 35 is a diagram for explaining a method for forming an intensity modulating signal to the acousto-optical modulator element in FIG. 34;

FIGS. 36A and 36B are diagrams showing states of shielding a high-order diffracted light component;

FIG. 37 is a diagram showing a polarization of a laser light as a generating source of a probe light and a reference light in obtaining an interference light including information about the minute displacements generated at the sample surface by the excitation light;

FIGS. 38A and 38B are diagrams for explaining the method of making phase jump correction on the photoacoustic signal (phase signal) according to FIG. 33;

FIG. 39 is a diagram showing the relation among the phase jump and a sampling interval of the phase shift signal;

FIG. 40A is a two-dimensional photoacoustic image (phase image) after a phase jump correction has been made on the photoacoustic signal (phase signal);

FIG. 40B is a diagram showing a phase shift signal taken along the line B--B' in FIG. 40A;

FIG. 41 is a flowchart showing another arrangement of the phase jump presence detecting and phase jump correcting process;

FIGS. 42A and 42B are diagrams showing means for correcting a phase jump of the photoacoustic signal according to FIG. 41;

FIG. 43A is a two-dimensional photoacoustic image (phase image) after a phase jump correction process has been done on a photoacoustic signal (phase signal) by another method;

FIG. 43B is a diagram showing a phase signal taken along the line B--B' in FIG. 43A; and

FIG. 44 is a diagram of another structural example of the photoacoustic signal detection apparatus.

DESCRIPTION OF THE PREFERRED EMBODIMENTS

A first embodiment of the present invention will be described with reference to FIGS. 5A to 16C. FIG. 5A shows the photoacoustic detection optical system according to the first embodiment. This optical system includes an excitation optical system 201, a heterodyne Twyman-Green interferometric optical system 202 for detecting a photoacoustic signal, and a signal processing system 203. A parallel beam 32 emitted from an Ar laser 31 (wavelength 515 nm) of the excitation optical system 201 is incident on an acousto-optical modulator 33. In FIG. 5A, a sine wave 98 with a frequency f_(C0) shown in FIG. 6A and a square wave 99 with a frequency f_(L) (f_(L) <f_(C0)) shown in FIG. 6B are respectively input to a signal synthesizer 88 to form a product of these two waveforms, which serves as a modulated signal 100 as shown in FIG. 6C, and this modulated signal 100 is input to the acousto-optical modulator 33. As a result, a first-order diffracted light 35, shifted in frequency by f_(C0), is intermittently output with a frequency of f_(L) from the acousto-optical modulator 33. In other words, as an excitation light, an intensity-modulated beam with a modulated frequency of f_(L), shifted in frequency by f_(C0), is obtained. A zero-order light 34 is intercepted by a diaphragm 36. After passing a beam splitter 37, the intensity-modulated beam 35 is expanded to a desired beam diameter by a beam expander 38, and caused to become an elliptic beam 40 by a cylindrical lens 39. Then, after reflected by a dichroic prism 41 (reflects wavelengths 600 nm or less, transmits wavelengths more than 600 nm), the elliptic beam 40 is focused only in the x-direction at a pupil 43, that is, the rear focal point 44 of an objective lens 42. With regard to the y-direction, since the cylindrical lens 39 can be regarded as a plate glass without a curvature, the elliptic beam is incident on the rear focal point 44 of the objective lens as a parallel light. In consequence, as shown in FIG. 8, a stripe beam 101 having a width in the x-direction and focused in the y-direction can be obtained as an excitation beam on the front focal point of the objective lens, that is, on the surface of a sample 47. Meanwhile, a light beam 49 which is about 10% of the intensity-modulated beam 35 is reflected by the beam splitter 37 and detected by a photoelectric converting element 50, such as a photodiode, and then, sent through an amplifier circuit 89 to the oscillator 87. At the oscillator 87, comparison is made between a set frequency f_(L) supplied from a modulation signal control circuit 90 and a measured frequency f_(L) ' detected by the photoelectric converting element 50, and in order for the two frequencies to coincide with each other, the oscillated frequency is adjusted minutely. The oscillator 87 is formed by a PLL (Phase Locked Loop) circuit or the like.

The excitation optical system 201 will be described with reference to FIGS. 7A and 7B. In FIGS. 7A and 7B, the focal point of the cylindrical lens 39 and the rear focal point 44 of the objective lens 42 coincide with each other, and the front focal point of the objective lens coincides with the surface of the sample 47. Therefore, as shown in FIG. 7A, as for the x-direction, because the beam 40 leaving the cylindrical lens 39 is focused at the rear focal point 44 of the objective lens 42, a beam 46 emerging from the objective lens 42 as a parallel light is incident on the surface of the sample 47. On the other hand, as shown in FIG. 7B, with regard to the optical path seen in the y-direction, since the cylindrical lens 39 can be regarded as a plate glass without a curvature, the beam 40 leaving the cylindrical lens 39 enters the objective lens 42 as a parallel light, and therefore, the beam 46 emerging from the objective lens 42 is focused on the surface of the sample 47. Consequently, as shown in FIG. 8, on the surface of the sample 47, a stripe beam 101 having a width in the x-direction and focused in the y-direction can be obtained as an excitation beam. Suppose Cu wiring patterns 102 and 103 are formed using an organic polymeric material 104, say, polyimide as an insulator as shown in FIG. 8. FIGS. 9A and 9B are sectional views showing an internal structure of the sample and heat diffusion regions produced by the excitation beam. The sample 47 has a structure in which Cu wiring patterns 102 and 103 with a thickness of 20 μm are formed on a ceramic substrate 109 with a 20-μm-thick polyimide 104 used as an insulator. Internal defects to be detected include an internal crack 107 in the Cu wiring pattern and separation 108 of the interface between the substrate and Cu pattern. An important point here is a difference in thermal properties between the Cu patterns 102 and 103, and the polyimide 104 surrounding the patterns. To be more specific, in the case of Cu, the thermal conductivity k is 403 [J·m⁻¹ ·k⁻¹ ·s⁻¹, the density ρ is 8.93 [X10⁶ g·m⁻³ ], and the specific heat c is 0.38 [J·g⁻¹ ·k⁻¹ ], while in the case of polyimide, the thermal conductivity k is 0.288 [J·m⁻¹ ·k⁻¹ ·s⁻¹ ], the density ρ is 1.36 [X10⁶ g·m⁻³ ], and the specific heat c is 1.13 [J·g⁻¹ ·k⁻¹ ]. A notable difference, above all else, is the heat conductivity k of Cu is 1400 times greater than that of polyimide. So, if the intensity-modulated frequency f_(L) of the excitation light is 50 kHz and the above values are substituted into the expression (1), the thermal diffusion length μ_(S) in the Cu patterns 102 and 103 is about 27 μm, and that of the polyimide portion 104 is about 1.1 μm. Consequently, as shown in FIGS. 9A and 9B, heat given in the light absorption region 105 in a stripe formed by the stripe-shaped excitation beam 101 is diffused widely in the Cu patterns 102 and 103 under inspection, and a heat diffusion region 106 is formed in a manner to extend across the section of the Cu pattern including the interface with the substrate. On the other hand, in the polyimide portion 104 excluded from the scope of inspection, heat is diffused in a small area, and the heat diffusion region is formed only in the surface area. Therefore, as shown in FIGS. 8, 9A and 9B, if the stripe-shaped excitation beam 101 is irradiated so as to cover a plurality of Cu wiring patterns 102 and 103, thermoelastic wave is generated by a thermal distortion wave resulting from a photoacoustic effect or a photothermal effect in the light absorption region 105, and a distribution 110 (indicated by a broken line) of minute displacements is produced at the surface of the sample. Further, in this minute displacement distribution 110, mixing of information does not occur, but individual items of internal information (containing an internal crack 107 and a separation 108) about the respective Cu wiring patterns 102, 103 and the polyimide portion 104 are reflected independently in the profile of the distribution. More specifically, if the stripe-shaped excition beam 101 is used, a plurality of objects under inspection having distinct thermal contrast can be excited simultaneously and can be detected independently, so that two-dimensional internal information about a sample can be detected with high speed. Referring to FIGS. 5A to 13B, description will next be made of the structure and the function of the heterodyne Twyman-Green interferometric optical system 202 for detecting a distribution 110 (broken line) of minute displacements of the sample surface caused by the photoacoustic effect. In FIG. 5A, the polarization direction of a linearly polarized beam 52 emitted from a He-Ne laser 51 (wavelength 633 nm) is set at 45° relative to the x-axis and the y-axis as indicated by 111 in FIG. 10A. The direction perpendicular to paper, as shown in FIG. 5A, is designated as the y-axis, and the direction at right angles with the y-axis is designated as the x-axis. As for the function of a polarization beam splitter 53, out of the incident light beam 52, a p-polarized light component 54 indicated by 112 in FIG. 10A passes through the polarization beam splitter 53, and enters an acousto-optical modulator 62, while an s-polarized light component 55 indicated by 113 in FIG. 10A is reflected by the polarization beam splitter 53. A sine wave with a frequency of f_(C1) equal to the one shown in FIG. 6A is input to the acousto-optical modulator 62 from an oscillator 91, and a first-order diffracted light 64 of the p-polarized light shifted in frequency by f_(C1). A zero-order light 63 is intercepted by diaphragm 65. This first-order diffracted light 64 of the p-polarized light is reflected by a mirror 66, and then passes through a polarization beam splitter 61.

On the other hand, the s-polarized light component 55 reflected by the polarization beam splitter 53 is reflected again by the mirror 56, and is incident on an acousto-optical modulator 57. A sine wave with a frequency of f_(C2) (f_(C1) ≠f_(C2)) equal to the one shown in FIG. 6A is input to the acousto-optical modulator 57 from the oscillator 91, and a first-order diffracted light 59 of the s-polarized light shifted in frequency by f_(C2) is obtained. A zero-order light 58 is intercepted by a diaphragm 60. The first-order diffracted light 59 of the s-polarized light is reflected by the polarization beam splitter 61, and is combined with the first-order diffracted light 64 of the p-polarized light transmitted through the polarization beam splitter 61. The thus produced combined light 67 has two-frequency orthogonal-polarized components, that is, two polarized beams intersecting at right angles and having a frequency difference of f_(C1) -f_(C2). After passing through a beam splitter 68, the combined light 69 is expanded to a desired beam diameter by a beam expander 70, and made into an elliptic beam as it passes through a cylindrical lens 71. This elliptic beam is separated by a polarization beam splitter 73 into a p-polarized beam 72 and an s-polarized beam 74. The p-polarized beam 72, which has been shifted in frequency by f_(C1), passes through the dichroic prism 41, and is focused only in the x-direction at the pupil 43, that is, the rear focal point 44 of the objective lens 42. On the other hand, with regard to the y-direction, since the cylindrical lens 71 is regarded as a plate glass without a curvature, the p-polarized beam 72 is incident on the rear focal point 44 of the objective lens 42 as a parallel light. The beam leaving the objective lens 42 as it passes through a λ/4 plate 45 becomes a circularly polarized beam 145, and as shown in FIG. 8, at the front focal point of the objective lens, i.e., on the surface of the sample 47, at the same incident position as the excitation beam 101, a stripe beam 190 is obtained as a probe beam having a width in the x-direction and focused in the y-direction. As shown in FIGS. 11A and 11B, the reflected light from the sample 47 contains information of minute displacement distribution 110 (broken line) as phase distribution, produced at the surface of the sample 47 caused by a photoacoustic effect. In FIG. 5A, the reflected light from the sample 47, after passing through the λ/4 plate 45, becomes an s-polarized beam, and after the beam passes through the objective lens 42, the beam again travels along the same optical path, and is reflected by the polarization beam splitter 73.

Meanwhile, the s-polarized beam 74 separated by the polarization beam splitter 73 has been shifted in frequency by f_(C2), and after passing through the λ/4 plate 75, becomes a circularly polarized light and is incident on a reference mirror 76.

The circularly polarized beam reflected by the reference mirror 76 passes again through the λ/4 plate 75, becomes a p-polarized light, and passes through the polarization beam splitter 73 as a reference light. In FIG. 12, numeral 114 denotes a polarization direction of the light reflected from the sample 47 which has been further reflected by the polarization beam splitter 73, and 115 denotes a polarization direction of the reflected light from the reference mirror 76. These beams of light intersect at right angles, and do not interfere with each other under this condition. So, a polarizing plate 79 is disposed at the rear of an imaging lens 78 to set the polarization direction to 45° as indicated by 116 in FIG. 12, whereby the two reflected beams of light interfere with each other to provide a heterodyne interference light 80 having a beat frequency of f_(B) =f_(C1) -f_(C2). As light phase distribution information, this heterodyne interference light 80 contains information of one-dimensional distribution in the x-direction of minute displacements produced at the surface of the sample 47 by the photoacoustic effect. After stray light is removed by passing through an interference filter 81 of a central wavelength of 633 nm, the interference light 80 passes through the imaging lens 78 to form an image on a storage type image sensor 82 such as a CCD linear image sensor. Since the surface of the CCD linear image sensor 82 is conjugated with the surface of the sample 47, naturally, a stripe-shaped interference light forms an image on the surface of the sensor, just like the probe beam formed on the surface of the sample 47. The beam splitter 68 causes reflection of about 10% beam out of the complex light 67 having two-frequency orthogonal polarized light components. The two polarized light components of this complex light are caused to interfere with each other by a polarizing plate 83 set at 45° polarization direction, so that a beat signal of f_(B) '=f_(C1) '-f_(C2) ' is detected by a photoelectric converting element 85, such as a photodiode. This beat signal is sent through an amplifier circuit 92 to a CCD linear image sensor driver control circuit 93. The driver control circuit 93 compares a setting beat frequency f_(B) supplied from a processor 96 and a measured frequency f_(B) ' detected by the photoelectric converting element 85, and adjusts finely the frequency f_(C1) or f_(C2) of the sine wave output from an oscillator 91 through the processor 96 and a modulation signal control circuit 90 so that the above-mentioned compared frequencies match. The oscillator 91 is formed by a PLL (Phase Locked Loop) circuit, for example.

The heterodyne Twyman-Green interferometric optical system 202 will now be described in greater detail with reference to FIGS. 7A, 7B, 13A, and 13B. As shown in FIGS. 7A and 7B, like in the excitation optical system 201, the focal point of the cylindrical lens 71 coincides with the rear focal point 44 of the objective lens 42, and the front focal point of the objective lens coincides with the surface of the sample 47. Therefore, as shown in FIG. 7A, with regard to the x-direction, the p-polarized beam 72 emerging from the cylindrical lens 71 is focused at the rear focal point 44 of the objective lens 42, so that the beam 145 is incident on the surface of the sample 47 as a parallel light.

On the other hand, as shown in FIG. 7B, in the incidence in the y-direction, since the cylindrical lens 71 can be regarded as a plate glass without a curvature, the beam 72 leaving the cylindrical lens 71 is incident on the objective lens 42 as a parallel light, the beam 145 emerging from the objective lens 42 is focused on the surface of the sample 47. As a result, as shown in FIG. 8, on the surface of the sample 47, a stripe beam 190 as a probe beam is obtained having a width in the x-direction and focused in the y-direction like the excitation beam at the same position as the excitation beam 101. Meanwhile, as shown in FIGS. 7A and 7B, the focal position of the cylindrical lens 71 coincides with the position of the reference mirror 76. Consequently, as shown in FIG. 7A, in the incidence in the x-direction, the s-polarized beam 74 leaving the cylindrical lens 71 is focused on the reference mirror 76, and as shown in FIG. 7B, in the incidence in the y-direction, the s-polarized beam 74 is incident on the reference mirror 76 as a parallel light.

As shown in FIGS. 13A and 13B, the front focal position of the objective lens 42 coincides with the surface of the sample 47, the rear focal position of the objective lens 42 coincides with the front focal position of the image forming lens 78, and the rear focal position of the image forming lens 78 coincides with the image pickup surface of the CCD one-dimensional sensor 82. In other words, this optical system is a bi-telecentric image forming optical system. Therefore, as shown in FIG. 13A, with regard to the x-direction, the parallel reflected light from the surface of the sample 47 passes through the objective lens 42, and is then focused at its rear focal position, and after passing through the image forming lens 78, becomes a parallel light again, and is incident on the CCD one-dimensional sensor 82. On the other hand, as shown in FIG. 13B, with regard to the y-direction, the divergent reflected light from the surface of the sample 47 as it passes through the objective lens becomes a parallel light, and after passing through the image forming lens 78, is focused at its rear focal position, that is, on the CCD one-dimensional sensor 82. As a result, on the CCD one-dimensional sensor 82, a stripe beam having a width in the x-direction and focused in the y-direction like the probe beam 190 on the sample 47 is obtained. On the other hand, as shown in FIGS. 13A and 13B, the position of the reference mirror 76 coincides with the front focal position of the image forming lens 78.

Therefore, as shown in FIG. 13A, with regard to the x-direction, after passing through the image forming lens 78, the divergent reflected light from the reference mirror 76 becomes a parallel light, is incident on the CCD one-dimensional sensor 82. As shown in FIG. 13B, with regard to the y-direction, after passing through the image forming lens 78, the divergent reflected light is focused at its rear focal position, that is, on the CCD one-dimensional sensor 82. Consequently, a heterodyne interference light, produced from the reflected light from the sample 47 and the reference light from the reference mirror 76, becomes a stripe beam like the probe beam 72, and is incident on CCD one-dimensional sensor 82, that is, a one-dimensional light interference signal in the x-direction is detected.

Description will be made of a method, using the signal processing system 203, for extracting the amplitude and the phase of minute displacements at the surface of the sample 47 caused by the photoacoustic effect from output signals of the CCD one-dimensional sensor 82 without being affected by the reflectance distribution and the undulations distribution on the surface of the sample 47. If the wavelength of the probe beam 72 incident on the surface of the sample 47 is denoted by λ, the amplitude by 1, the reflection coefficient of the surface of the sample 47 by a_(S), the reflection coefficient at the reference light path by a_(r), the light phase difference between the optical path of the probe light and the optical path of the reference light, including changes of phase caused by undulations of the surface of the sample 47 by φ, minute displacements at the surface of the sample 47 caused by the photoacoustic effect by A, and the amount of phase change relative to the intensity modulation signal by θ, then a heterodyne interference light I incident on one pixel of the CCD one-dimensional sensor 82 is expressed by the expression (2). ##EQU3##

Further, from A<<1, the above expression can be approximately transformed into the following expression (3). ##EQU4##

Here, A cos (2πf_(L) t+θ) is a term expressing a complex amplitude of the minute displacement on the surface of the sample 47 caused by the photoacoustic effect. A detection signal I_(D) (n+i)(n+i is a number of times of accumulation and output of the CCD one-dimensional sensor 82, where i is an arbitrary integer, >0) output from one pixel of the CCD one-dimensional sensor 82 is given by the following expression in which the storage time of the sensor is denoted by α/f_(B). ##EQU5##

Next, for the expression (4), conditions which meet the following items are obtained.

(1) the second term≠0

(2) the amount of phase shift=π/2 or π/4 for the number of times i of accumulation and output in the second term.

(3) the third term≠0

(4) the amount of phase shift π/2 for the number of times i of accumulation and output in the third term

(5) the fourth term=0

The conditions obtained are as shown by the following expressions (5) and (6) when p and s are integral numbers, and α is a non-integral number. ##EQU6##

For example, if s=6 and p=2, α=21/8, f_(L) =50 kHz, f_(B) =210 kHz can be set, so that the expression (4) can be reduced to the following expression (7). ##EQU7##

The above-mentioned parameters α=21/8, f_(L) =50 kHz, and f_(B) =210 kHz are all set by the processor 96, and those parameters are sent to the CCD one-dimensional sensor driver control circuit 93 and the modulation signal control circuit 90, and according to the values of the parameters, the drive of the CCD linear image sensor and the oscillators 87 and 91 is controlled. For the parameters α, f_(L), and f_(B), known data related to the heat diffusion lengths at depths to be detected of individual materials is stored previously. A method of setting the sensor storage time α/f_(B) is as follows. From the above-mentioned setting beat frequency f_(B) and the parameter α sent from the processor 96, the CCD linear image sensor drive control circuit 93 generates read shift pulses of frequency f_(B) /α for the CCD linear image sensor, and according to the read shift pulses and clock pulses, the CCD linear image sensor 82 is driven.

In the expression (7), the first term is the d.c. component, the second term is the modulation component related to the light phase difference φ between the probe light path and the reference light path, including changes of phase due to undulations of the surface of the sample 47, and the phase shift amount relative to the number of times i of accumulation and output is π/4. The third term is the modulation component related to the light phase difference φ and the amplitude A and the phase θ of the photoacoustic, and the phase shift amount relative to the number of times i of accumulation and output is π/2. If the signal is to be obtained by using i=1 to i=8 in the expression (7), that is, for one period for the second term and for two periods for the third term, then we have the following expressions (8), (9), (10), (11), (12), (13), (14), and (15). ##EQU8##

In practice, after a detection signal I_(D) (n+i) from the CCD one-dimensional sensor 82 is amplified by an amplifier circuit 94, ten data sets obtained when i=1 to i=8 are used in the expression 7, that is, a total of 80 accumulated and output data sets are stored in a two-dimensional memory 95. If the number of pixels of the CCD one-dimensional sensor 80 is 256, it follows that 256×80 items of data have been stored. If data of the w-th pixel at the (n+i)-th accumulation and output is designated by (n+i, w), the order in which the data is stored in the two-dimensional memory 95 is: ##EQU9##

Meanwhile, from the two-dimensional memory 95, 80 accumulated and output data sets are read one pixel by one pixel, and sent to the processor 96. ##EQU10##

Using 80 accumulated and output data sets for each pixel, the processor 96 performs arithmetic operations shown below to obtain the reflectance a_(s) ² of the surface of the sample 47, the light phase difference φ between the optical path of the probe light and the optical path of the reference light, including changes of phase due to the undulations of the surface of the sample 47, the amplitude of a photoacoustic signal in which the reflectance of the surface of the sample 47 has been corrected, and the phase θ of the photoacoustic signal in which changes of phase due to the undulations of the surface of the sample 47.

By calculating a sum of the expressions (8) to (15), the reflectance a_(s) ² of the surface of the sample 47 is given by the following expression (16). ##EQU11##

The light phase difference φ between the probe light path and the reference light path, including changes of phase due to the undulations of the surface of the sample 47, is given by the following expression (17), derived from the expressions (8), (10), (12), and (14). ##EQU12##

The amplitude of the photoacoustic signal, that is, minute displacement A thereof on the surface of the sample 47 is given by the expression (18), in which the reflectance of the surface of the sample 47 has been corrected, derived from the expressions (8), (9), (12), (13) and (16). ##EQU13##

The phase of the photoacoustic signal, that is, the phase change φ thereof relative to the intensity-modulated signal of the excitation light is given by the following expression (19), in which the changes of phase due to the undulations of the surface of the sample 47 have been corrected, derived from the expressions. (8), (9), (12), (13), (16) and (17). ##EQU14##

FIG. 5B shows a structural example of the processor 96. The processor 96 has the signal processor a which exchanges signals with the CCD one-dimensional sensor driver control circuit 93, the memory 95, an X-Y TABLE 48 and the modulation signal control circuit 90, and which sets data and parameters. The processor 96 includes a surface reflectance arithmetic unit 96a for calculating the reflectance of the sample surface corresponding to the pixels of CCD 82 by the expression (16) shown above, a surface undulations arithmetic unit 96c by the expression (17), a photoacoustic amplitude arithmetic unit 96d by the expression (18), and a photoacoustic phase arithmetic unit 96e by the expression (19). The processor 96 also includes a display selector 96f for receiving calculation results of the four arithmetic units, selecting one of the calculation results in response to a selection signal which is set externally, and displaying that calculation result on the display 97.

FIGS. 15A, 15B and 15C show an example of a photoacoustic signal detected in this embodiment. From FIG. 15A, it will be understood that a minute displacement 110 (broken line) on the surface of the Cu wiring pattern 102 caused by an internal crack 120 is greater than that of the surface of the normal Cu wiring pattern 103. Similarly, in a distribution 121 of the amplitude A of the photoacoustic signal in FIG. 15B and in a distribution 124 of the phase θ+φ of the photoacoustic signal before correction of the changes of phase due to the undulations of the surface of the sample 47 in FIG. 15C, there are sharp signals 123 (FIG. 15B) and 126 (FIG. 15C) by the internal cracks.

On the other hand, FIGS. 16A, 16B and 16C show an example of a photoacoustic signal detected in this embodiment in a case where there are undulations distributed on the surface of a sample 47. As shown in FIG. 16B, a distribution 137 of a phase θ+φ of a photoacoustic signal before phase correction is affected by changes of phase due to undulations of the surface of the sample 47, so that the signal-to-noise ratio of the signal decreases greatly, and as a result, it is difficult to recognize an internal crack 135. However, as shown in FIG. 16C, in a distribution of the phase signal in which phase correction has been done by the expression 19, the distribution 139 of the phase signal θ is not affected by changes of phase and a signal 141 due to the internal crack 135 can be recognized clearly.

By processing the detection signal from the above-mentioned CCD one-dimensional sensor by the processor 96 while scanning the sample 47 sequentially in the x- and y-directions by using the X-Y stage 48, a two-dimensional photoacoustic image of the whole surface of the sample 47 can be obtained and displayed on a TV monitor.

As has been described, according to the present embodiment, in contrast to the conventional point-scanning method in which information is detected one point after another, a plurality of points being measured are excited simultaneously using an excitation beam in a stripe form, light interference is used in detecting a photoacoustic signal from the respective points being measured so that an interference light is detected as parallel-output data obtained simultaneously. Thus, the photoacoustic signal at a plurality of points being measured of the sample can be detected in parallel simultaneously, so that two-dimensional information on the sample can be detected at high speed.

Further, according to the present embodiment, by a single CCD one-dimensional sensor, it is possible to simultaneously detect four items of information relative to the surface and the inside of the sample, including the reflectance distribution of the sample surface, the undulations distribution of the sample surface, the amplitude distribution of the photoacoustic signal, and the phase distribution of the photoacoustic signal, with the result that a compound assessment of a sample becomes possible.

Further, according to the present embodiment, it is possible to detect the reflectance distribution of the sample surface, the undulations distribution of the sample surface, and a photoacoustic signal for which the sway of the optical path has been corrected, and thus, it is possible to detect information relative to the surface and the inside of the sample with stability and high sensitivity.

Further, according to the present embodiment, by setting the intensity-modulated frequency of the excitation beam so that the heat diffusion length due to the photoacoustic effect is equal to or longer than the depth of the interface between the Cu wiring pattern under inspection and the ceramic substrate, inspection of the interface becomes possible.

Further, according to the present invention, when extracting a photoacoustic signal from the light interference signal, a digital frequency filtering process is used instead of the analog process, a photoacoustic signal can be detected with high sensitivity and accuracy without being not much affected by higher harmonic components.

In the present embodiment, examples have been described in which the present invention can be applied to samples having a plurality of objects under inspection which exhibit a sharp thermal contrast, but the present invention can be applied sufficiently to samples made of a homogeneous material and containing an internal crack. Also in this case, since a plurality of points being measured on a sample can be excited, the above-mentioned effects can be expected. Next, a second embodiment of the present invention will be described with reference to FIGS. 17 to 25. FIG. 17 shows a photoacoustic detection optical system according to the second embodiment. This optical system comprises an excitation optical system 301, a heterodyne differential interferometric optical system 302 for detecting a photoacoustic signal, and a signal processing system 303. In an excitation optical system 301, the structure and the function of the part for obtaining an intensity-modulated beam 35 of the modulation frequency f_(L) are the same as in the first embodiment, so their description will be omitted. After being passed through a beam splitter 37, the intensity-modulated beam is expanded to a desired beam diameter by a beam expander 38, and is focused by a cylindrical lens 150 at its focal position only in the y-direction. This focal position 159 coincides with the front focal position of an off-axis relay lens 152. The beam having passed the relay lens 152 again becomes a parallel light, which is reflected by a dichroic prism 153 (reflects wavelengths 600 nm or less, transmits wavelengths more than 600 nm), and then is incident on the pupil of an objective lens 154, that is, the rear focal position 155. On the other hand, with regard to the x-direction, since the cylindrical lens 150 can be regarded as a plate glass without a curvature, the beam incident as a parallel light on the relay lens 152, is focused at the rear focal position 155 of the objective lens 154, which coincides with the rear focal position of the relay lens 152. As a result, the front focal position of the objective lens 154, that is, on the surface of the sample 47, a stripe beam 186 having a width in the x-direction and focused in the y-direction can be obtained as the excitation beam.

The beam splitter 37 reflects a beam 49 corresponding to about 10% of the intensity-modulated beam 35 as in the first embodiment, and after being detected by a photoelectric converting element 50 such as a photodiode, the beam 49 is sent to an oscillator 89 through an amplifier circuit 89. The oscillator 87 compares a set frequency f_(L) sent from a modulation signal control circuit 90 and a measured frequency f_(L) detected by the photoelectric converting element 50, and finely adjusts the oscillation frequency so that the compared frequencies match. The oscillator 87 is formed by a PLL (Phase Locked Loop) circuit, for example.

The excitation optical system will be described in greater detail with reference to FIGS. 18A and 18B. In FIGS. 18A and 18B, the focal position 159 of the cylindrical lens 150 coincides with the front focal position of the off-axis relay lens 152, the rear focal position of the relay lens 152 coincides with the rear focal position 155 of the objective lens 154, and the front focal position of the objective lens 154 coincides with the surface of the sample 47. Therefore, as shown in FIG. 18A, with regard to the y-direction, since a beam 151 emerging from the cylindrical lens 150 is focused at its focal position 159, that is, the front focal position of the relay lens 152, the beam having passed the relay lens 152 again becomes a parallel light which is incident on the objective lens 154, and the beam 156 leaving the objective lens 154 is focused on the surface of the sample 47. Further, since the relay lens is off its axis, the focal position of the relay lens is off the center of the objective lens 154. On the other hand, as shown in FIG. 18B, since the cylindrical lens 150 can be regarded as a plate glass without a curvature, the beam 151 leaving the cylindrical lens 150 as a parallel lens is incident on the relay lens 152, and is focused at the rear focal position 155 of the objective lens 154, which rear focal position 155 coincides with the rear focal position of the relay lens 152. As a result, a beam 156 leaving the objective lens 154 becomes a parallel light and is incident on the surface of the sample 47. In consequence, on the surface of the sample 47, a stripe beam 186 having a width in the y-direction and focused in the y-direction can be obtained as an excitation beam.

FIGS. 20A and 20B show a distribution 185 (broken line) of minute displacements at the sample surface caused by a photoacoustic effect produced along a light absorption region 183 by irradiating the above-mentioned excitation beam 186 in a stripe form to the sample including Cu wiring patterns 102 and 103 formed using an organic polymeric material 104 such as polyimide as an insulator in the same manner as in the first embodiment. Like in the first embodiment, internal information (internal crack 107, separation 108) on the Cu wiring patterns 102 and 103 and internal information on the polyimide portion 104 are independently reflected, without being mixed, in the distribution 185 of the minute displacements. In other words, by using this stripe-shaped excitation beam 186, a plurality of objects under inspection which exhibit a sharp thermal contrast can be excited simultaneously, so that two-dimensional internal information about the sample can be obtained with high speed.

The structure and the function of the heterodyne differential interferometric optical system 302 for detecting the distribution 185 (broken line) of minute displacements at the sample surface caused by a photoacoustic effect will be described with reference to FIGS. 17, 21A, 21B, and 25. In the heterodyne differential interferometric optical system 302 in FIG. 17, the structure and the function of the part for obtaining two-frequency orthogonal polarized beams, that is, the complex light 67 having light components intersecting at right angles in directions 112 and 113 as shown in FIG. 10B and having a frequency difference of f_(C1) -f_(C2) between them is exactly the same as in the first embodiment, and their description is omitted. Here, the direction perpendicular to paper as shown in FIG. 17 is designated as the x-axis and the direction intersecting at right angles to the x-axis is designated as the y-axis. After the complex light 67 of the two-frequency orthogonal polarized beams is passed through the beam splitter 68, the light is expanded to a desired beam diameter by the beam expander 70, and then, made into an elliptic beam by a cylindrical lens 160. With regard to the y-direction, since the cylindrical lens 160 can be regarded as a plate glass without a curvature, this elliptic beam, which is a parallel light in relation to the y-direction, is reflected as a parallel light by the beam splitter 162, and is separated into a p-polarized beam 164 and an s-polarized beam 165, both parallel beams, by a Wollaston prism 163 (or Rochon prism) placed at the focal position of the cylindrical lens 160. Because the position of the Wollaston prism 163 coincides with the front focal position of the relay lens 166, the principal rays of these two beams having passed through the relay lens 166 become parallel to each other, and the respective beams are focused at the rear focal position 187 of the relay lens 166.

Since the rear focal position 187 of the relay lens 166 coincides with the front focal position of the relay lens 168, the principal rays of the two beams, after passing through the relay lens 168, travel through the dichroic prism 153, and are focused at the rear focal position 155 of the objective lens 154, which rear focal position 155 coincides with the rear focal position of the relay lens 168. At the same time, the two beams are incident as parallel beams on the rear focal position 155 of the objective lens 154. On the other hand, with regard to the x-direction, the beam emerging from the cylindrical lens 160 is focused on the Wollaston prism 163, and then the beam travel through the relay lens 166 and becomes a parallel beam, and after passing through the dichroic prism 153, the parallel beam is focused at the rear focal position of the objective lens 154. As a result, at the front focal position of the objective lens 154, that is, on the surface of the sample 47, a stripe beam 186 having a width in the x-direction and focused in the y-direction can be obtained as an excitation beam. Two beams emerging from the objective lens 154 after passing through a λ/4 plate, become circularly polarized beams 169 and 170. Thus, as shown in FIG. 19, at the front focal position of the objective lens, that is, on the surface of the sample 47, a stripe beam 181 having a width in the x-direction and focused in the y-direction like the excitation beam 186 can be obtained as a probe beam at the same position as the excitation beam 186, and also, at a position a little away from the probe beam 181, a stripe beam 182 having a width in the x-direction and focused in the y-direction like the probe beam can be obtained as a reference beam. As shown in FIGS. 21A and 21B, a reflected light from the position of the probe beam 181 of the sample 47 has as phase distribution information the distribution 185 (broken line) of minute displacements produced on the surface of the sample 47 by the photoacoustic effect. Meanwhile, the reference beam 182 is so arranged to be incident at a position as close to the probe beam 181 as possible as shown in FIGS. 21A and 21B in a range where minute displacements 185 are produced on the surface of the sample 47 by the excitation beam 186, namely, outside the heat diffusion region 184 in FIGS. 20A and 20B. Reflected beams of light from the positions of the probe beam 181 and the reference beam 182 on the sample 47 pass through the λ/4 plate and become an s-polarized beam and a p-polarized beam, and those polarized beams, after passing through the objective lens 42, travel again along the same optical paths, and after combined by the Wollaston prism 163, pass through the beam splitter 162.

Reference numeral 114 in FIG. 12 denotes the polarization direction of the reflected light from the position of the probe beam 181, while 115 denotes the polarization direction of the reflected light from the position of the reference beam 182. Since the two reflected beams of light intersect at right angles to each other, they do not interfere with each other under this condition. So, by inserting a polarizing plate 79 after the image forming lens 78 so as to set the polarizing direction to 45° as indicated by 166 in FIG. 12, the reflected beams are caused to interfere with each other to provide a heterodyne interference light 171 having a beat frequency of f_(B) =f_(C1) -f_(C2). This heterodyne interference light 171 contains as light phase distribution information a one-dimensional x-direction distribution of minute displacements produced on the surface of the sample 47 by the photoacoustic effect. This interference light 171 is passed through an interference filter 81 of a central wavelength of 633 nm to eliminate stray light, and then the interference light 171 travels through the image forming lens 78 and forms an image on the storage type solid image pickup element 82, such as a CCD one-dimensional sensor, for example. Since the image pickup surface of the CCD one-dimensional sensor 82 is in image forming relationship with the surface of the sample 47, naturally, the interference light in a stripe shape forms an image on the image pickup surface like the probe beam formed in a stripe on the surface of the sample 47. Meanwhile, the beam splitter 68 reflects a beam corresponding to about 10% of the complex light 67 of two-dimensional orthogonal polarized beams just like in the first embodiment. The two polarized components of this beam are caused to interfere with each other by a polarizing plate 83 with its polarization direction set at 45° direction as indicated by 116 in FIG. 12, so that a beat signal of f_(B) '=f_(C1) -f_(C2) ' is detected by the photoelectric converting element 85 such as a photodiode. This beat signal is sent through the amplifier circuit 92 to the CCD one-dimensional sensor driver circuit 93. The driver control circuit 93 compares the setting beat frequency f_(B) sent from the processor 96 and the measured frequency f_(B) ' detected by the photoelectric converting element 85, and finely adjusts the frequency f_(C1) or f_(C2) of the sine wave from the oscillator 91 through the processor 96 and the modulation signal control circuit 90 so that those two frequencies match. The oscillator 91 is formed by a PLL (Phase Locked Loop) circuit, for example.

The heterodyne differential interferometric optical system 302 will be described in greater detail with reference to FIGS. 22, 23, 24, and 25. As shown in FIGS. 22 and 23, the focal position of the cylindrical lens 160 coincides with the position of the Wollaston prism 163, the position of the Wollaston prism 163 coincides with the front focal position of the relay lens 166, the rear focal position 187 of the relay lens 166 coincides with the front focal position of the relay lens 168, the rear focal position of the relay lens 168 coincides with the rear focal position 155 of the objective lens 154, and the front focal position of the objective lens 154 coincides with the surface of the sample 47. Therefore, as shown in FIG. 22, with regard to the y-direction, since the cylindrical lens 160 can be regarded as a plate glass without a curvature, a complex light 161 of two-frequency orthogonal polarized components leaving the cylindrical lens 160 is incident as a parallel light on a Wollaston prism 163, and subsequently separated into a p-polarized beam 164 and an s-polarized beam 165. Because the position of the Wollaston prism 163 coincides with the front focal position of the relay lens 166, the principal rays of the two beams, after passing through the relay lens 166, become parallel to each other, and the respective beams are focused at the rear focal position 187 of the relay lens 166. Since the rear focal position 187 of the relay lens 166 coincides with the front focal position of the relay lens 168, the principal rays of the two beams, after passing through the relay lens 168, are focused at the rear focal position 155 of the objective lens 154, which rear focal position 155 coincides with the rear focal position 155 of the objective lens 154. As the two beams are simultaneously incident as parallel beams at the rear focal position 155 of the objective lens 154, the two beams 169 and 170 emerging from the objective lens 154 are both focused on the surface of the sample 47. The principal rays of the two beams are parallel to each other.

On the other hand, as shown in FIG. 23, with regard to the x-direction, the beam leaving the cylindrical lens 160 is focused at the Wollaston prism 163, and as the beam passes through the relay lens 166, it becomes a parallel light, and is focused at the rear focal position 155 of the objective lens 154 by the relay lens 168. Therefore, the beams 169 and 170 leaving the objective lens 154 both become parallel beams, and are incident on the surface of the sample 47. Consequently, as shown in FIG. 19, a stripe beam 181 having a width in the x-direction and focused in the y-direction like the excitation beam 186 can be obtained as a probe beam at the same position as the excitation beam 186 on the surface of the sample 47, and also, a stripe beam 182 having a width in the x-direction and focused in the y-direction like the probe beam 181 can be obtained as a reference beam at a position a little away from the probe beam 181.

As shown in FIGS. 24 and 25, the front focal position of the objective lens 154 coincides with the surface of the sample 47, the rear focal position 155 of the objective lens 154 coincides with the rear focal position of the relay lens 168, the front focal position of the relay lens 168 coincides with the rear focal position 187 of the relay lens 166, the front focal position of the relay lens 166 coincides with the position of the Wollaston prism 163, the position of the Wollaston prism 163 coincides with the front focal position of the image forming lens 78, and the rear focal position of the image forming lens 78 coincides with the image pickup surface of the CCD one-dimensional sensor 82. In other words, as shown in FIG. 24, with regard to the y-direction, the principal rays of the two divergent reflected beams from the surface of the sample 47, after passing the objective 154, are focused at its rear focal position 155, and at the same time, the two beams are incident as parallel beams on the relay lens 168. Since the rear focal position of the objective lens 154 coincides with the rear focal position of the relay lens 168, the principal rays of the two beams, after passing through 168, become parallel to each other, and the two beams are simultaneously focused both at the front focal position of the relay lens 168, that is, at the rear focal position 187 of the relay lens 166. After passing through the relay lens 166, the two beams are combined by the Wollaston prism 163, and then the combined light travels as a parallel light through the image forming lens 78 and is focused at the rear focal position of the image forming lens 78, namely, the CCD one-dimensional sensor 82. On the other hand, as shown in FIG. 25, with regard to the x-direction, the two parallel reflected beams from the surface of the sample 47, after passing through the objective lens 154, are focused at the rear focal position 155 thereof, and the two beams travel through the relay lens 168 to become parallel beams which are focused at the front focal position of the relay lens 166, that is, at the position of the Wollaston prism 163. Further, the combined light, after passing through the image forming lens 78, again becomes a parallel light and is incident on the CCD one-dimensional sensor 82. As a result, on the CCD one-dimensional sensor 82, a stripe beam having a width in the x-direction and focused in the y-direction like the probe beam 181 and the reference beam 182 on the sample is obtained. In other words, a heterodyne interference light obtained from the reflected rays of the probe beam 181 and the reference beam 182 becomes a stripe beam on the CCD one-dimensional sensor 82, so that a one-dimensional light interference signal in the x-direction is detected. The structure and the function of the signal processing system 303 are exactly the same as those of the signal processing system 203 in the first embodiment, and therefore, like in the first embodiment, from an output signal of the CCD one-dimensional sensor 82, the amplitude and the phase of minute displacements at the surface of the sample 47 produced by a photoacoustic effect can be extracted without being affected by the reflectance distribution and the undulations distribution of the surface of the sample 47.

By processing a detection signal from the above-mentioned CCD one-dimensional sensor by the processor 96 while scanning the sample 47 sequentially in the x- and y-directions by using the X-Y stage 48, a two-dimensional photoacoustic image of the whole surface of the sample 47 can be obtained, and displayed on the TV monitor 97.

As has been described, according to the present embodiment, instead of the conventional so-called point scanning method for detecting information from one point after another, as shown in the first embodiment, a plurality of points being measured are excited in parallel simultaneously by a stripe-shaped excitation beam, and because light interference is used to detect a photoacoustic signal produced at the respective points, an interference light is detected in parallel simultaneously so that the photoacoustic signal at the plurality of points being measured on the sample is detected in parallel simultaneously, and thereby two-dimensional internal information on the sample can be detected at high speed.

Further, according to the present embodiment, like in the first embodiment, it is possible with only one CCD one-dimensional sensor to simultaneously detect a total of four items of information relative to the surface and the inside of the sample, namely, the reflectance distribution of the sample surface, the undulations distribution of the sample surface, the amplitude distribution of the photoacoustic signal, and the phase distribution of the photoacoustic signal, and thus, a compound assessment of a sample is possible.

Further, according to the present embodiment, like in the first embodiment, it is possible to detect the reflectance distribution of the sample surface, the undulations distribution of the sample surface, and the photoacoustic signal for which the fluctuation of the optical path has been corrected, and thus, it is possible to detect information relative to the surface and the inside of the sample with high sensitivity and stability.

Further, according to the present embodiment, like in the first embodiment, inspection of an interface inside the sample is possible by setting the intensity-modulated frequency of the excitation beam so that the heat diffusion length due to the photoacoustic effect is equal to or longer than the depth of the interface being inspected between the Cu wiring pattern and the ceramic substrate.

Further, according to the present embodiment, like in the first embodiment, for extracting a photoacoustic signal from the light interference signal, a digital frequency filtering process is used instead of the analog frequency filtering process, so that detection of the photoacoustic signal can be performed with high sensitivity and high accuracy while being hardly subject to the influence of high harmonic components.

Further, according the present embodiment, a differential interferometric optical system is used as the interferometric optical system for detecting minute displacements of the sample surface caused by the photoacoustic effect. More specifically, instead of obtaining a reference light from a reference mirror separately installed, a reflected light of the reference beam, which is incident near the probe light and is reflected by the sample surface, is used as the reference light, so that the probe light and the reference light travel along substantially the same optical path and through the same optical system, and thus, the fluctuation of the optical path length and the displacement of the wave front between the two beams of light are reduced greatly, and the detection accuracy and the detection sensitivity of a photoacoustic signal are improved remarkably.

Moreover, since the need to provide a reference light path is obviated, the optical system is simplified and increased in stability, and the detection accuracy of the photoacoustic signal improves.

Incidentally, in this embodiment, description has been made of the examples in which the present invention is applied to samples having a plurality of objects under inspection with a notable thermal contrast, but the present invention can be applied sufficiently to samples made of a homogeneous material containing an internal crack, for example. Even in this case, a plurality of points being measured on the sample can be excited simultaneously, and therefore, the above-mentioned effects can be expected.

A third embodiment of the present invention will be described with reference to FIGS. 26 and 27. FIG. 26 shows a photoacoustic detection optical system according to a third embodiment. This optical system includes an excitation optical system 201, a heterodyne Twyman-Green interferometric optical system 402 for detecting a photoacoustic signal, and a signal processing system 403. The structure and the function of the excitation optical system 201 are exactly the same as in the first embodiment, and their description are omitted. The structure of the heterodyne Twyman-Green interference optical system 402 is the same as in the first embodiment, only differences being that the beam splitter 68 for detecting a beat signal, the polarizing plate 83, and the photoelectric converting element 85 have been removed and a parallel output type photoelectric converting element array 191 is used in place of the storage type CCD one-dimensional sensor 82 for detecting an interference signal in the heterodyne Twyman-Green interferometric optical system 202 in the first embodiment, and therefore, its description is omitted.

As shown in FIG. 27, the light interference signal output from the respective pixels of the parallel output type photoelectric converting element array 191 is amplified for the individual pixels by a group of pre-amplifiers 192 arranged as many as the number of the pixels, and then, the intensity-modulated signal 50a detected by the photoelectric converting element 50 is sent as a reference signal to a group of lock-in amplifiers 193 and the modulated frequency component included in the light interference signal is sent as the photoacoustic signal to the group of lock-in amplifiers 193, so that the amplitude and the phase of the minute displacements of the surface of the sample 47 produced by the photoacoustic effect are detected for all pixels simultaneously. The detected photoacoustic signal is converted into digital data by a group of A/D converter 194, and subsequently, sent to a parallel-in, serial-out type shift register 195 to be converted into a one-dimensional signal. A position signal of the X-Y stage 48 and an output signal from the shift register 195 are processed by a processor 196, and the photoacoustic signal at the respective points of the sample 47, that is, a two-dimensional photoacoustic image of the whole surface of the sample 47 is obtained and displayed on the TV monitor 97. Meanwhile, in this embodiment, the non-storage type parallel output photoelectric converting element array 191 is used as the interference light detecting sensor, but a storage type may be used. In this case, the signal processing system 403 can be used as is. Or, in the signal processing system 403, it is possible to remove the group of lock-in amplifiers 193, and obtain signals whose phase is shifted among them by controlling the storage time in the photoelectric converting element array based on the expression 4 to the expression 6 like in the first or second embodiment and make the processor to perform arithmetic operations based on the expression 16 to the expression 19.

This embodiment can be applied sufficiently to samples having a plurality of objects under inspection which exhibit a conspicuous thermal contrast, and also to samples made of a homogeneous material containing an internal crack as shown in FIGS. 8, 9A, and 9B.

As has been described, according to the present embodiment, instead of the conventional so-called point scanning method for detecting information from one point after another, as shown in the first and second embodiments, a plurality of points being measured are excited in parallel simultaneously by a stripe-shaped excitation beam, light interference is used to detect a photoacoustic signal produced at the respective points, and an interference light is detected in parallel so that the photoacoustic signal at the plurality of points being measured on the sample is detected simultaneously, whereby two-dimensional internal information on the sample can be detected at high speed.

Further, if a storage type one-dimensional sensor is used in the present embodiment, as shown in the first embodiment, it is possible by only one one-dimensional sensor to simultaneously detect a total of four items of information on the surface and the inside of the sample, namely, the reflectance distribution of the sample surface, the undulations distribution of the sample surface, the amplitude distribution of the photoacoustic signal, and the phase distribution of the photoacoustic signal, so that a compound assessment of a sample becomes possible.

Further, if a storage type one-dimensional sensor is used in the present embodiment, as shown in the first embodiment, it is possible to detect the reflectance distribution of the sample surface, the undulations distribution of the sample surface, and the photoacoustic signal for which the fluctuation of the optical path has been corrected, and thus, detection of information on the surface and the inside of the sample with high sensitivity and stability becomes possible.

Further, if a storage type one-dimensional sensor is used in the present embodiment, as shown in the first embodiment, inspection of an interface inside the sample is possible by setting the intensity-modulated frequency of the excitation beam so that the heat diffusion length due to the photoacoustic effect is equal to or longer than the depth of the interface being inspected between the Cu wiring pattern and the ceramic substrate.

Further, if a storage type one-dimensional sensor is used in the present embodiment, like in the first embodiment, for extracting a photoacoustic signal from the light interference signal, a digital frequency filtering process is used instead of the analog frequency filtering process, so that detection of the photoacoustic signal can be performed with high sensitivity and high accuracy while being hardly subject to the influence of high harmonic components.

Incidentally, it is possible to store the light interference signal from the pixels of the non-storage type photoelectric array 191 in the two-dimensional memory, and thereafter, read the light interference signal from one pixel after another and detect the photoacoustic signal by one lock-in amplifier as a one-dimensional signal.

A fourth embodiment of the present invention will be described with reference to FIGS. 28 to 32. FIG. 28 shows a photoacoustic detection optical system in the fourth embodiment. This optical system includes an excitation optical system 501, a heterodyne Twyman-Green interferometric optical system 202 for detecting a photoacoustic signal, and a signal processing system 203. The structure and the function of the heterodyne Twyman-Green interferometric optical system 202 and the signal processing system 203 are exactly the same as in the first embodiment, and their description is omitted.

Whereas the stripe-shaped excitation beam is used in the first, second and third embodiments, one notable difference of this fourth embodiment from the foregoing ones is that a multiple-spot-beam parallel irradiation optical system 197 is adopted in the excitation optical system 501. The other component parts are the same as in the first to the third embodiments. With reference to FIG. 31, the multiple-spot-beam parallel irradiation optical system 197 will be described. An expanded parallel light from the beam expander 38 passes through the stripe-shaped opening 210a of a mask 210 and becomes a stripe beam and is incident on a one-dimensional minute lens array 211. The rear focal positions of the minute lenses coincide with the front focal position 212 of the relay lens 213, the rear focal position of the relay lens 213 coincides with the rear focal position 214 of the objective lens 42, and the front focal position of the objective lens 42 coincides with the surface of the sample 47. The beams from the one-dimensional minute lens array 211 are focused at the front focal position 212 of the relay lens 213, and after passing through the relay lens 213, become parallel beams, and after passing through the objective lens 42, are focused as convergent spot beams on the surface of the sample 42. Meanwhile, the principal rays of the spot beams are parallel to each other. FIG. 31 shows the state that the respective spot beams irradiate the sample simultaneously. The number of the spot beams is matched with the number of the pixels of the CCD one-dimensional sensor 82 for light interference detection, and the distances between them are arranged so that the heat diffusion regions 217 generated by the spot beams do not overlap each other. The probe beam for heterodyne interference detection is shaped in a stripe like in the first to third embodiments. The structure and the function of the signal processing system 203 are exactly the same as in the first embodiment. Like in the first embodiment, from the output signal of the CCD one-dimensional sensor 82, the amplitude and the phase of the minute displacements of the surface of the sample 47 caused by the photoacoustic effect can be extracted without being affected by the reflectance distribution and the undulations distribution of the surface of the sample 47.

By processing a detection signal from the above-mentioned CCD one-dimensional sensor by the processor 96 while scanning the sample 47 sequentially in the x- and y-directions by using the X-Y stage 48, a two-dimensional photoacoustic image of the whole surface of the sample 47 can be obtained, and displayed on the TV monitor 97.

This embodiment can be applied sufficiently to samples having a plurality of objects under inspection which exhibit a conspicuous thermal contrast, and also to samples made of a homogeneous material containing an internal crack as shown in FIGS. 8, 9A, and 9B.

As has been described, according to the present embodiment, instead of the conventional so-called point scanning method for detecting information from one point after another, a plurality of points being measured are excited in parallel simultaneously by irradiating a plurality of spot beams in parallel simultaneously, because light interference is used to detect a photoacoustic signal produced at the respective points, an interference light is detected in parallel simultaneously so that the photoacoustic signal at the plurality of points being measured on the sample is detected in parallel simultaneously, and thereby two-dimensional internal information on the sample can be detected at high speed.

Further, according to the present embodiment, because the heat diffusion regions of the respective excitation beams do not overlap each other, a resulting effect is improved resolution in detecting a photoacoustic image.

Further, according to the present embodiment, like in the first embodiment, by only one CCD one-dimensional sensor, it is possible to simultaneously detect a total of four items of information relative to the surface and the inside of the sample, i.e., the reflectance distribution of the sample surface, the undulations distribution of the sample surface, the amplitude distribution of the photoacoustic signal, and the phase distribution of the photoacoustic signal, and thus, a compound assessment of a sample becomes possible.

Further, according to the present embodiment, like in the first embodiment, it is possible to detect the reflectance distribution of the sample surface, the undulations distribution of the sample surface, and the photoacoustic signal for which the fluctuation of the optical path has been corrected, and thus, detection of information relative to the surface and the inside of a sample with high sensitivity and stability becomes possible.

Further, according to the present embodiment, like in the first embodiment, inspection of an interface inside the sample is possible by setting the intensity-modulated frequency of the excitation beam so that the heat diffusion length due to the photoacoustic effect is equal to or longer than the depth of the interface being inspected between the Cu wiring pattern and the ceramic substrate.

Further, according to the present embodiment, like in the first embodiment, for extracting a photoacoustic signal from the light interference signal, a digital frequency filtering process is used instead of the analog frequency filtering process, so that detection of the photoacoustic signal can be performed with high sensitivity and high accuracy while being hardly subject to the influence of high harmonic components.

Incidentally, in the present embodiment, the storage type CCD one-dimensional sensor is used for detecting an interference light, but as in the third embodiment, a non-storage type parallel-output photoelectric converting element array may be used. In this case, it is only necessary to use the signal processing system 403 in the third embodiment.

In the first to third embodiments described above, the excitation beam and the probe beam both in a one-dimensional stripe form are used, but a beam in a two-dimensional form having a certain area may be used. In this case, a two-dimensional sensor is used for detecting an interference light as a matter of course. Likewise, also in the fourth embodiment, it is possible to arrange a plurality of spot beams in a two-dimensional form and use a two-dimensional sensor.

Another embodiment of the present invention will next be described with reference to FIGS. 33 to 44.

First of all, the photoacoustic signal detection apparatus is described, and FIG. 34 shows an example of its structure. In this case, the photoacoustic signal detection apparatus comprises an excitation optical system 301, a heterodyne Mach-Zehnder interference optical system 302 for detecting a photoacoustic signal, and a signal processing system 300, if the component sections are roughly divided. A parallel laser beam 282 from an Ar laser oscillator (wavelength 515 nm) 281 has its intensity modulated to a desired form by an acousto-optical modulating element 283. An oscillator 268 outputs a sine wave signal 98 with a frequency of f_(B) as shown in FIG. 35(a), and an oscillator 269 outputs a square wave signal 99 with a frequency of f_(L) (f_(L) <f_(B)) as shown in FIG. 35(b). These signals 98 and 99 are combined by the signal synthesizer 270 to supply a product of the two waveforms, and the resultant intensity modulation frequency signal 100 is as shown in FIG. 35(c). By this intensity modulation frequency signal 100, the parallel laser beam 282 striking the acousto-optical modulating element 283 has its intensity modulated to a desired form. As a result, the acousto-optical modulating element 283 intermittently outputs a first-order diffracted light 285 with a frequency of f_(L), which has been shifted by f_(B) '. In other words, an intensity-modulated beam with an intensity-modulated frequency of f_(L) shifted by f_(B) can be obtained as an excitation beam. In this process, a zero-order light 284 is intercepted by a diaphragm 286. The intensity-modulated beam 285 from the acousto-optical modulating element 283 has its beam diameter expanded by a beam expander 287 to a desired length, and then, the beam 185 is focused by a lens 288 at its rear focal position 289. At this rear focal position 289, there is provided a pin-hole 290, by which the high-order diffracted light elements are removed. As shown in FIG. 36A, the high-order diffracted light components 105a and 105b present at the surrounding area of the peak portion 105 at the focusing spot are intercepted by the pin-hole 290, and in consequence, the light intensity distribution after passage of the pin-hole 290 becomes the one having only the peak portion 105 as shown in FIG. 36B. Since the rear focal position 289 is also the front focal position of the lens 291, the luminous flux after passage of the pin-hole 290 becomes a parallel excitation light 292 as it passes through the lens 291. The parallel excitation light 292 is reflected by a dichroic prism (reflects wavelengths 600 nm or less, transmits wavelengths more than 600 nm) 293, and travels through a λ/4 plate 247, and is focused at the front focal position 250 of an objective lens 248, that is, the excitation beam 292 falls on the focusing position of a sample 251 as a light spot having a light intensity distribution like the one shown in FIG. 36B. In other words, the front focal position 289 of the lens 291 is in a conjugate and confocal relation with the front focal position 250 of the objective lens 248. At the front focal position (focusing spot) 250 on the sample 251 to which the parallel excitation light 292 in a focused state is irradiated, an ultrasonic wave (thermoelastic wave) is generated by a thermal distortion wave caused by a photoacoustic effect, and at the same time, at the focusing spot 250 on the surface of the sample 251, minute displacements occur, which change periodically at the intensity-modulated frequency of f_(L) of the parallel excitation light 292.

Meanwhile, in the Mach-Zehnder interferometric optical system 302, the polarization direction of a linearly polarized beam 232 from a He-Ne laser oscillator (wavelength 633 nm) 231 is set at 45° respectively to the x- and the y-directions as indicated as the polarization direction 106 in FIG. 37 (the direction perpendicular to paper of FIG. 34 is designated as the x-axis and the direction at right angles to the x-axis is designated as the y-axis). Of the linearly polarized beam 232 from the He-Ne laser oscillator 231, a p-polarized component 234 shown as a p-polarized component 107 in FIG. 37 is allowed by a polarization beam splitter 233 to transmit therethrough and is incident on an acousto-optical modulating element 276, while an s-polarized component 235 shown as an s-polarized component 108 in FIG. 37 is reflected by the polarization beam splitter 233 in the direction of a mirror 253. Meanwhile, as a sine wave 98 of frequency f_(B) shown in FIG. 35(a) is supplied to the acousto-optical modulating element 276 from an oscillator 215, the acousto-optical modulating element 276 outputs a first-order diffracted light 237 shifted in frequency by f_(B) . The first-order diffracted light 237 with the accompanying zero-order light 236 removed by the diaphragm 238 is expanded to a desired beam diameter by a beam expander 239, and then, is focused at the rear focal position 241 of a lens 240. Since at the rear focal position 241, there is provided a pin-hole 242, the high-order diffracted light components 105a and 105b present at the surrounding area of the peak portion 105 at the focusing spot are intercepted, and after passage of the pin-hole 242, the light intensity distribution of the first-order diffracted light 237 becomes the one having only the peak portion 105 as shown in FIG. 36B. Since the rear focal position 241 of the lens, after passage of the pin-hole 242, the first-order diffracted light 237 again becomes a parallel light 244 as it passes the lens 243. This parallel light 244 comprises the p-polarized beam, and therefore, after passing as it is through a beam splitter 245, the light 244 is reflected by a mirror 246, and then, travels through the dichroic prism 293 and the λ/4 plate 247 and becomes a circularly polarized light. The circularly polarized light focused by the objective lens 248 at its front focal position 250, namely, at the focusing position on the sample 251 as a converged light spot having a light intensity distribution similar to the one shown in FIG. 36B. More specifically, the front focal position 241 of the lens 243 is in a conjugate and confocal relation with the front focal position 250 of the objective lens 248. The reflected light from the front focal position (focusing spot) 250 on the sample 251 on which the parallel light 244 is focused, contains the information of minute displacements produced on the surface of the sample 251 as phase information. The reflected light, after passing the objective lens, becomes a parallel light, and by traveling through a λ/4 plate 247, is made into an s-polarized light, which propagates back along the same optical path and is reflected by a polarization beam splitter 245. The s-polarized beam 261 from the polarization beam splitter 245 passes through a non-polarization beam splitter 260 and is caused to interfere with a reference light 259 reflected from the non-polarization beam splitter 260.

The reference light 259 is made from the s-polarized component 235 reflected by the polarization beam splitter 233. The s-polarized component 235 from the polarization beam splitter 233 is reflected by the mirror 253, and has its beam diameter expanded to a desired length by a beam expander 254, and then, is focused by a lens 255 at its rear focal position 256. By a pin-hole 257 provided at the rear focal position 256, the high-order diffracted light components 105a and 105b present around the peak portion 105 at the focusing spot are intercepted as shown in FIG. 36A, with the result that the light intensity distribution of the s-polarized component 235, after passing the pin-hole, 257 becomes the one having only the peak portion 105 as shown in FIG. 36B. Since the rear focal position 256 also serves as the front focal position of the lens 258, the s-polarized component 235 having passed the pin-hole 257 is obtained as a parallel reference light 259 as it comes out of the lens 258. This parallel reference light 259, after being reflected by the non-polarization beam splitter 260, is caused to interfere with the s-polarized beam 261 reflected from the surface of the sample 251 and passed through the non-polarization beam splitter 260, and thereby an interference light 262 is obtained. The interference light 262 contains minute displacements of the surface of the sample 251 caused by the photoacoustic effect as light phase information. The interference light 262 travels through a lens 263, and is detected as an interference intensity signal by a photoelectric converting element 267, such as a photodiode, disposed at the rear focal position 264 of the lens 263. In the Mach-Zehnder interferometric optical system 302, the front focal position 241 of the lens 243, the front focal position 256 of the lens 258, the front focal position 250 of the objective lens 248, and the rear focal position 264 of the lens 263 are located in conjugate and confocal relation with one another. In addition, since there is provided a pin-hole 265 at the rear focal position 264 of the lens 263, stray light occurring in the objective lens 248, an interference component occurring in the transparent thin film on the sample 251, and high-order diffracted light components occurring produced by the minute undulations on the surface of the sample 251 can be intercepted, so that the minute displacements caused by the photoacoustic effect can be detected by the photoelectric converting element 267 in an improved condition.

In the manner as described, the interference intensity signal is obtained by the Mach-Zehnder interferometric optical system 302, and then, the interference intensity signal is processed by the signal processing system 300 as specified. The interference intensity signal contains information relative to the amplitude A and the phase θ connected with the minute displacement at the surface of the sample 251, which is produced at the intensity-modulated frequency f_(L), and this information is obtained by using the signal processing system 300. As shown in FIG. 34, the interference intensity signal from the photoelectric converting element 267 is sent through a pre-amplifier 271 to a phase detection circuit 272 which extracts only a d.c. component and a f_(L) frequency component from the interference intensity signal. By using a sine wave of frequency f_(L) from an oscillator 269 as a reference signal, a lock-in amplifier 273 obtains the amplitude and the phase of the frequency component of f_(L) in the end. From the amplitude and the phase, the processor 274 obtains the amplitude A and the phase θ according to the minute displacement at the surface of the sample 251. The amplitude A and the phase 8 thus obtained contain thermoelastic information as to the heat diffusion region (V_(th)) defined by the intensity-modulated frequency f_(L). Therefore, if there is an internal defect, such as a crack, in the heat diffusion region (V_(th)), the amplitude A and the phase θ change, accordingly, and from such changes, the presence of the crack is detected. In this process, the laser-light-irradiated positions on the sample 251 are controlled through an X-Y stage 252 by the processor 274 which specifies one position after another as the position whose data is to be updated. The real laser-light-irradiated position is known by the processor 274 from a position detection signal from the X-Y stage 252. If such an arrangement is made that the processor 274 processes the intensity-modulated frequency component from the lock-in amplifier 273 in conjunction with the real laser-light-irradiated position each time the laser light is irradiated to the sample 251, then the photoacoustic signal corresponding to the real laser-light-irradiated positions can be obtained to output a two-dimensional photoacoustic image on a display 275. In this case, the processor 274 will be performing a phase jump detection and correction process when a phase jump exists, in addition to a general process to obtain the photoacoustic image. FIG. 33 shows a routine for detecting a phase jump and correcting the phase jump in line units in the x-direction.

The phase jump detection and correction process will be described with reference to FIGS. 38A and 38B.

FIG. 38A shows a phase shift signal 413 having a notable phase jump at a pixel P₁. The phase jump detection process in this case is arranged such that a check is made at the block 401 in FIG. 33 whether the sign is the same for the phase signals θ (P₀) and θ (P₁) at two adjacent pixels P₀ and P₁ on the premise that a phase jump has not occurred in the phase signal θ (P₀) at the first pixel P₀. If there is an inversion of the sign between the θ (P₀) and θ (P₁), supposing that there could be a phase jump in the phase signal θ (P₁), a check is also made whether a difference in phase, that is, the absolute value of θ (P₁)-θ (P₀) is greater than 2 (π-ε) (the constant ε will be described later). As is clear from FIG. 38A, since θ (P₁)-θ(P₀)|>2 (π-ε), a decision is made that a phase jump exists. To the phase signal θ (P₁) at the pixel P₁ for which a decision has been given that a phase jump exists, 2π or -2π is added by the phase jump correction process. Which is added is decided according to the phase difference, namely, the sign of θ (P₁ ) ' θ (P₀). If the phase difference is minus, it follows that the θ (P₁) took a phase jump of -2π, and 2π is added to the θ (P₁), whereas conversely, if the phase difference is plus, -2π is added to the θ (P₁). In this manner, the phase jump correction is performed. In the case shown in FIG. 38A, in the block 402 in FIG. 33, 2π is added to the phase signal θ (P₁) at the pixel P₁ to correct the phase jump. Thereafter, the value of i is incremented by +1, the process mentioned above is performed for the pixels P₁ and P₂. Since a phase jump has been carried out for the phase signal θ (P₁) at the pixel P₁, the inversion of the sign does not occur between the phase signals θ (P₁) and θ (P₂), and therefore, a phase jump correction is not performed for the phase signal θ (P₂) at the pixel P₂. So is the case with the pixels P₃ and P₄. From the phase signal θ (P₃) to the phase signal θ (P₄), there is an inversion of the sign, but, since the absolute value of the phase difference is not greater than 2(π-ε), a phase jump correction is not carried out. FIG. 38B shows the phase signal 414 after a phase jump correction has been done for the phase signal 413. The abnormality of the phase signal 413 due to the phase jump at the pixel P₁ has been eliminated. In the forgoing description, in the phase jump correction, whether to add 2π or -2π is decided according to the sign of the phase difference between the adjacent two pixels P_(i) and P_(i+1), but, of course, this decision may be made according to the signs of the phase signals θ(P_(i)) and θ(P_(i+1)).

The constant ε introduced in the calculation of the phase difference will next be described with reference to FIG. 39. As has been described, the photoacoustic signal is obtained by detecting at certain sampling intervals the thermal distortion of the sample surface caused by the photoacoustic effect or the photothermal effect generated by irradiation of the intensity-modulated light to the focusing point on the sample. Therefore, as shown in FIG. 39, there occurs such a case in which at sampling intervals of some length, the photoacoustic signal is detected at positions R₁ and R₂, for example, away from the point Q where a phase jump actually occurs. As a result, the detected phase signal values θ (R₁) and θ (R₂) are respectively θ (R₁)<π and θ (R₂)>-π, so that the phase difference between the two phase signals is smaller than 2π, and if the criterion is set at 2π, there is a high possibility that a phase jump is overlooked, and it is difficult to make a decision on presence or absence of a phase jump. To make it possible to correctly render a presence/ absence decision of a phase jump even in the above case, the constant ε is introduced. To be more specific, the value of ε is set suitably for individual cases to tolerate a phase shift signal error resulting from a round-off error owing to the discretization and digitization of the detected photoacoustic signal, and a calculation error in processing the detected signal. In this embodiment, the constant ε is set at π/6 to execute a phase jump correction.

FIG. 40A shows a phase image after a phase jump correction has been done on the phase image shown in FIG. 4A described. FIG. 40B is a view of the phase shift signal 412 taken along the line B--B' in FIG. 40A, with the phase shift signal 111 in FIG. 4B shown for comparison. It will be understood that the sharp change of phase caused by the crack is shown correctly.

In the above description, a case is assumed in which a phase jump correction process on the phase signal for one line in the x-direction in the two-dimensional phase image is executed line after line simultaneously with detection of a phase signal. In actual processing, the phase jump correction process can be expanded to the y-direction based on the partial two-dimensional phase signal stored tentatively until then. Also, it is possible to simultaneously perform the phase jump correction process in the x- and y-directions on the tentatively stored two-dimensional phase signal after all the phase signal is detected.

As has been described, in the photoacoustic signal detection method according to the present invention, as the abnormality of the phase signal caused by a phase jump of the photoacoustic signal, or in other words, omission of phase information is eliminated, it becomes possible to detect a photoacoustic signal steadily and securely, and information relative to the subsurface of the sample can be obtained with high accuracy. Moreover, the phase jump correction process for the photoacoustic signal is performed on the detected phase signal, so that this process can be executed readily only by a partial addition of process function to the signal processing system without altering the optical system of the photoacoustic signal processing apparatus of the prior art.

In the phase jump detection and correction process described above, the phase jump detection and the subsequent phase jump correction are carried out according to a change of the sign of the phase signal between the two adjacent pixels and a difference in the phase signal between the two pixels. Besides this, there is another possible method of phase jump detection and correction. This method is to let the processor 274 execute the phase jump detection and correction process, shown in FIG. 41, to the phase image, shown in FIG. 4A, which was processed by the processor 274. In this principle of this phase jump detection and correction process, a characteristic is utilized that generally, the phase gradient changes suddenly from plus to minus or minus to plus in the neighborhood of the pixel at which a phase jump occurs. More specifically, in the phase shift signal 518 shown in FIG. 42A, for example, for the phase signals θ (P₁), θ (P₂) and θ (P₃) at the three consecutive pixels on the same straight line, the phase gradients Ψ_(b) and Ψ_(a) respectively between the pixels P₁ and P₂ and between the pixels P₂ and P₃ are calculated (to be more precise, the phase gradients Ψ_(b) and Ψ_(a) are obtained respectively as tan Ψ_(b) and tan Ψ_(a)). Then, a decision is made whether Ψ_(b) is plus or minus. If Ψ_(b) is plus and Ψ_(a) <-2 (ε-π) (ε is defined as of the same character as the one mentioned above, in this embodiment the constant e is set at π/6, and a pitch between pixels P_(i+1) and P_(i) is assumed to be one pixel), a decision is made that a phase jump has occurred, and accordingly, 2 is added to θ(P₂). In this way, a phase jump correction is executed. Likewise, for the phase signal 519 in the case of FIG. 42B, from the fact that Ψ_(b) is minus and θ_(a) >2(π-ε), a decision is made that a phase jump has occurred, and a phase jump correction is made by adding -2π to θ(P₃). In the foregoing description, the phase gradients Ψ_(a) and Ψ_(b) are calculated between two adjacent pixels, but it is possible to calculate a phase gradient between two pixels separated more than two pixels and perform a phase jump correction according to the calculation result.

FIG. 43A shows a phase image after a phase jump correction process has been executed by the phase jump detection and correction process to the phase image shown in FIG. 4A mentioned above. FIG. 43B shows the phase signal 512 taken along the line B--B' in FIG. 43A along with the phase signal 111 shown in FIG. 4B for comparison. As can be seen from these figures, the sharp change in phase caused by a crack is correctly shown.

As mentioned above, by the phase jump detection and correction process by the other method, too, the deviation of the phase signal due to a phase jump of the photoacoustic signal, that is to say, an omission of phase information can be eliminated. Therefore, the photoacoustic signal can be detected steadily and securely and information as to the inside of the sample cam be obtained with high accuracy. Furthermore, a phase jump correction process for the photoacoustic signal is carried out to the phase signal detected, and therefore, can be executed readily by only a partial addition of process function to the signal processing system without making alterations to the optical system in the photoacoustic signal detection apparatus of the prior art.

In the foregoing description, cases are assumed in which the phase jump correction process on the phase shift signal for every line in the x-direction in a two-dimensional phase image is executed line after line simultaneously with the phase shift signal detection process. In actual processing, however, the phase jump correction process can be expanded also to the y-direction based on a partial two-dimensional phase shift signal stored temporarily. It is also possible to perform the phase jump correction process simultaneously in the x- and the y-directions to the temporarily stored two-dimensional phase shift signal after all the phase shift signal is detected. Furthermore, it is possible to simultaneously execute this phase jump correction process in combination with the phase jump detection and correction process shown in FIG. 33. Moreover, in making a decision on the presence or absence of a phase jump, it is possible to judge whether a phase jump exists not only according to criteria based on a change of the sign of the phase shift signal between two adjacent pixels and a difference in the phase shift signal between those two pixels, but also according to criteria of a combination of the degree of the above-mentioned phase shift gradients and the signs (polarities) of the phase shift gradients with the above-mentioned criteria, or according to a logical product of all those criteria. On the other hand, in the phase jump correction process, it is possible to decide whether to add 2π or -2π according to a criteria of a combination of the sign (polarity) of a difference in phase between two adjacent pixels and the signs (polarities) of the above-mentioned phase shift gradients.

Finally, description will be made of a photoacoustic signal detection apparatus in another structure to which the present invention can be applied.

FIG. 44 shows the structure, a substantial difference of which from the one shown in FIG. 34 is that a PZT (piezoelectric) element 226 is provided newly below the sample 251 for detecting a photoacoustic signal in place of the above-mentioned Mach-Zehnder interferometric optical system. The structure of an excitation optical system 306 is the same as the one shown in FIG. 34, except that a mirror 225 is used in place of the dichroic prism 293. An output signal from the PZT element 226 contains information about the amplitude A and the phase θ of the minute displacements at the surface of the sample 251 at the intensity-modulated frequency f_(L). These items of information are obtained by a signal processing system 307. As illustrated, from the output signal from the PZT element 226, the lock-in amplifier 273 obtains through the pre-amplifier 227 the amplitude and phase of the frequency component of f_(L) by using the sine wave of frequency f_(L) from the oscillator 269 as a reference signal. From those amplitude and phase, the processor 274 obtains the amplitude A and the phase θ corresponding to the minute displacements at the surface of the sample 251. The amplitude A and the phase θ contain information relative to thermoelastic properties in the heat diffusion region (V_(th)) defined at the intensity-modulated frequency f_(L). Therefore, if there is an internal defect such as a crack in the heat diffusion region V_(th), the amplitude A and the phase θ vary, and from these variations, the presence of an internal defect is known. In this process, the laser-light-irradiated positions on the sample 251 are controlled through the X-Y stage by the processor 274 which specifies one position after another as the position whose data is to be updated, and the real laser-light-irradiated can be known by the processor 274 from a position detection signal from the X-Y stage 252. If an arrangement is made such that the processor 274 processes the intensity-modulated frequency component from the lock-in amplifier 273 in conjunction with the real laser-light-irradiated position each time the laser light is irradiated to the sample 251, then the photoacoustic signal corresponding to the real laser-light-irradiated positions can be obtained so as to output a two-dimensional photoacoustic image on a display 275. In this case, the processor 274 performs a phase jump detection and correction process when a phase jump exists, in addition to its general process to obtain the photoacoustic image.

The above-mentioned one other structure can be applied to photoacoustic detection apparatuses which use a stripe beam in the embodiments shown up to FIG. 32. If the structure using the excitation oscillation optical system and the PZT element shown in FIG. 44 is adopted in a photoacoustic detection apparatus using the above-mentioned stripe beam as the excitation light, then an advantage is obtained that the probe light and the interferometric optical system can be done away with, and therefore, the structure of the apparatus can be simplified. 

What is claimed is:
 1. A photoacoustic signal detection method comprising:irradiating an excitation light focused by a focusing optical system in a state of at least one dimensional linear shape simultaneously, intensity modulated by a desired frequency, to an at least one dimensional linear shape portion being measured on the surface of a sample simultaneously; irradiating a one dimensional shape probe light to said one dimensional linear shape portion being measured on the surface of the sample simultaneously; detecting a plurality of heterodyne interference light simultaneously by a reflected light of said one dimensional probe light and a specified one dimensional shape reference light with a detector in conjugate relation with said surface of said sample, said detector provided with a plurality of photoelectric converting elements in the state of the at least one dimensional linear shape corresponding to said one dimensional linear shape portion being measured; detecting at least one dimensional thermal distortions obtained by each of a plurality of frequency components equal to said intensity-modulated frequency at each of a plurality of points along said one dimensional shape portion being measured in accordance with variation with time on each of said plurality of heterodyne interference light comprising intensity signals detected by said each of photoelectric converting elements of said detector; and detecting information relative to a one dimensional cross-sectional surface being measured of the sample from a one dimensional thermal distortion obtained by each of the plurality of said frequency components at each of the plurality of points along said one dimensional shape portion.
 2. The photoacoustic signal detection method according to claim 1, wherein the intensity-modulated excitation light irradiated to said at least one dimensional linear shape portion being measured is a beam in a continuous, linear shape on said sample.
 3. The photoacoustic signal detection method according to claim 1, wherein the intensity-modulated excitation light irradiated to said at least one dimensional linear shape portion being measured is a row of spot beams arranged in a linear line shape on said sample.
 4. The photoacoustic signal detection method according to claim 3, wherein intervals of spot beams in the row are arranged so that heat diffusion regions caused by the respective spot beams do not overlap each other.
 5. The photoacoustic signal detection method according to claim 1, further comprising the steps of dividing said probe light into two light beams;irradiating one of said divided beams of the probe light to the same position as said excitation light; irradiating the other of said divided beams of the probe light as a reference light to a vicinity of the irradiated position by said excitation light; and detecting an interference light of two reflected beams of said one of the divided probe light and said reference light with said detector.
 6. The photoacoustic signal detection method according to claim 5, wherein the irradiated position by said excitation light and the irradiated position by said reference light are spaced at least more than the heat diffusion length caused by said excitation light.
 7. The photoacoustic signal detection method according to claim 1, wherein said interference light intensity signals are changed or integrated for a specified time by said detector before detection.
 8. The photoacoustic signal detection method according to claim 1, wherein the interference light intensity signal from said detector are output as a one-dimensional signal in a time series from said plurality of photoelectric converting elements.
 9. The photoacoustic signal detection method according to claim 1, wherein the interference light intensity signals from said detector are output in a parallel form from said plurality of photoelectric converting elements.
 10. The photoacoustic signal detection method according to claim 7, wherein said heterodyne interference light is stored at least one time at an interval of α/f_(B) (where α=(2S+4P+1)/8, 1/f_(B) =1/f_(L) ·(2S-4P+1)/(2S+4P+1)), at each of the photoelectric converting elements of said detector, and detecting said thermal distortion based on the at least one stored signal data outputted at each storing.
 11. The photoacoustic signal detection method according to claim 9, wherein said thermal distortion is detected in a parallel form from said interference light intensity signal output in a parallel form from said plurality of photoelectric converting elements.
 12. The photoacoustic signal detection method according to claim 1, wherein said intensity-modulated frequency is set so that the heat diffusion length due to the photoacoustic effect is at least substantially equal to the depth of an interface being measured in said sample.
 13. A photoacoustic detection apparatus comprising:excitation means for irradiating an intensity-modulated excitation light in a state of at least a one dimensional linear shape to an at least one dimensional linear shape portion being measured on a sample surface, said excitation means including a light source and intensity modulation means for generating said excitation light by intensity-modulating a light beam from said light source by a desired frequency; light interference means for causing interference between a probe light and a reflected light of a specified reference light by irradiating a specified one dimensional shape probe light, simultaneously with said excitation light, to said at least one dimensional linear shape portion being measured; interference light detection means for detecting said interference with a detector in conjugate relation with said sample surface, said detector comprising a plurality of photoelectric converting elements corresponding to said one dimensional linear shape portion being measured; and information detection means for detecting thermal distortion of a frequency component equal to said intensity-modulated frequency at said one dimensional linear shape portion being measured from a detected interference light intensity signal in order to detect information relative to the surface and the subsurface of said one dimensional linear shape portion being measured on the sample from detected thermal distortion of the frequency component.
 14. The photoacoustic detection apparatus according to claim 13, wherein said excitation means has a cylindrical lens installed along the irradiation path of said excitation light.
 15. The photoacoustic detection apparatus according to claim 13, wherein said excitation means includes a minute lens array comprising minute lenses arranged in a straight line along an irradiation path of said excitation light.
 16. The photoacoustic detection apparatus according to claim 15, wherein said minute lens array is arranged so that spot beams in a row formed on said sample surface by said minute lens array are located at such intervals that heat diffusion regions by the respective spot beams do not overlap each other.
 17. The photoacoustic detection apparatus according to claim 13, wherein said detector of said interference light detection means is formed by a storage type photoelectric converting element.
 18. The photoacoustic detection apparatus according to claim 13, wherein said detector of said interference light detection means is formed by a non-storage type photoelectric converting element.
 19. The photoacoustic detection apparatus according to claim 13, wherein said light interference means has means for dividing said probe light, wherein one of the divided probe light beams is irradiated to said at least one dimensional linear shape portion being measured, an other of the divided probe light beams is irradiated as a reference light to the vicinity of said at least one dimensional linear shape portion being measured, and said interference light detection means detects an interference light caused by said reflected light of said two divided probe beams.
 20. The photoacoustic detection apparatus according to claim 19, wherein said light interference means is so structured that a space between said two divided probe beams on said sample surface is at least a heat diffusion length by said excitation light.
 21. The photoacoustic detection apparatus according to claim 13, wherein said interference light is stored at least one time at an interval of α/f_(B) (where α=(2S+4P+1)/8, 1/f_(B) =1/f_(L) ·(2S-4P+1)/(2S+4P+1)), at each of the photoelectric converting elements of said detector, and detecting said thermal distortion based on the at least one stored signal data outputted at each storing. 